KR102630856B1 - Intraocular lens insertion tool - Google Patents

Abstract

The present invention relates to an intraocular lens insertion device used to insert an intraocular lens into an eye.
The purpose of the present invention is to provide a technology for preventing deformation or damage of the intraocular lens when the intraocular lens is inserted into a minimized corneal incision by an intraocular lens insertion device.

Description

INTRAOCULAR LENS INSERTION TOOL}

The present invention relates to an intraocular lens insertion device used to insert an intraocular lens into an eye.

Vision correction surgery is a surgical procedure for people who do not focus accurately on the retina, such as myopia or hyperopia. Currently, surgery is mainly performed to correct the problem by removing the part of the cornea that refracts light.

Representative vision correction surgeries include LASIK and LASEK. LASIK surgery is a method of correcting vision by creating a corneal flap and then irradiating a laser to the stroma of the cornea. There is less pain and faster recovery, but there are concerns about side effects such as dry eye syndrome due to the formation of corneal flaps.

LASEK is a method of vision correction after removing corneal epithelial cells. While it has the advantage of being resistant to shock and requiring less corneal cutting, even people with advanced degrees of surgery can receive it, it usually causes pain for 2 to 3 days, although it varies depending on the individual, and recovery is slower than LASIK or SMILE LASIK.

Smile LASIK has faster recovery than LASEK and almost no pain, is stronger against impact than LASIK, and requires less cutting volume.

Intraocular lens implantation is a surgery that corrects vision by inserting a lens into the eye. Laser surgery is a good option in cases where the cornea is too thin, the shape of the cornea is poor, or the refractive error is so severe that surgery to remove the cornea is burdensome. It can be used as an alternative.

Typically during these intraocular lens implantation procedures, the intraocular lens is first inserted through the surgical incision into the distal orifice of an insertion tube provided at the distal end portion of the intraocular lens insertion device body, and then through the distal orifice of the insertion tube. It is inserted into the eye by pushing the intraocular lens (maintained in a compact deformed state inside the body) outward.

Meanwhile, intraocular lenses are made of various materials. The original material for previous intraocular lenses was polymethyl methacrylate (PMMA). PMMA is a strong and durable material, but it has the problem that the corneal incision must be as large as the lens optic body within the eye.

In these cases, astigmatism may occur after surgery and affect vision. Therefore, at this time, in order to minimize astigmatism, the corneal incision must be minimized. For this purpose, various flexible materials such as collamer, hydrophobic acrylic, hydrophilic acrylic, PEG-PEA/HEMA/styrene copolymer, and silicone are currently used so that the intraocular lens can be inserted into the minimized corneal incision. After this intraocular lens is folded and mounted within the intraocular lens insertion device, it is forcibly pushed by the intraocular lens insertion device through the minimized corneal incision, is inserted into the corneal incision, and is then unfolded and positioned within the eye. . At this time, intraocular lenses made of these materials are less strong than intraocular lenses made of conventional materials, so there is a risk of tearing. In addition, it is necessary to reduce the rotation phenomenon that may occur within the eye when the intraocular lens is injected depending on the pressure at which the intraocular lens is injected into the eye.

In this way, it is necessary for the operator to insert the lens into the eye without damaging it and proceed with the procedure quickly and accurately.

Korean registered patent KR 10-1393025 Korean registered patent KR 10-1418269 Korean published patent KR 10-2023-0098213 Korean Published Patent KR 10-2015-0035982

An object of the present invention is to provide a technique for preventing deformation, rotation or damage of the intraocular lens when the intraocular lens is inserted into a minimized corneal incision by an intraocular lens insertion device.

A minimally invasive intraocular lens insertion device according to an embodiment of the present invention includes a cylindrical body having a distal end inserted into an incision hole formed in ocular tissue and a receiving portion for storing and disposing the intraocular lens, and press-fitting into the body. and a plunger that moves the intraocular lens within the body and discharges it into the eye from the distal end by pressing the intraocular lens stored in the storage unit from the distal end.

The plunger is formed at the tip of the plunger, has a lens discharge portion that directly contacts the intraocular lens and discharges the intraocular lens to the tip of the main body, and has a diameter set smaller than the diameter of the through hole of the main body. An insertion penetrating portion capable of advancing or retreating inside the main body and having a pressure plate portion that expands up and down or left and right at the rear end is formed, and the lens discharge portion includes a first spring and a shock absorbing shock inside the first spring. It is composed of a fixing part and a discharging part configured to contain an absorbent material, wherein the fixing part and the discharging part are assembled together, the first spring and the shock absorbing material are received together in the fixing part and the discharging part, and the fixing part and the discharging part are assembled together. It is assembled by combining the first engaging protrusion of the top and the second engaging protrusion of the discharge part, and the insertion penetration part is built into the main body together with the second spring, and has an inner peripheral surface of the second spring inside the second spring. Accordingly, the insertion penetrating portion penetrates, one end of the second spring is caught on an end of the narrow inner surface of the main body, the other end of the second spring is caught on the second spring locking portion formed in the hold portion, and the user When pressing the pressure plate by placing a finger on the hold portion, the discharge portion of the lens discharge portion discharges the intraocular lens stored in the lens storage portion to the distal end, and at the same time, the second spring is extended to extend the intraocular lens. It is characterized by being placed within the eye without damaging the eye.

The plunger includes a control unit capable of controlling the voltage input to the first spring and the second spring, a pressure sensor that detects the amount of pressure applied to the intraocular lens from the lens discharge unit, and the control unit measures the amount of pressure applied to the intraocular lens. Transmitting the voltage input to the first spring and the second spring and the amount of pressure applied to the intraocular lens from the lens discharge unit detected by the pressure sensor to a central server, and receiving an output value from the central server The controller further includes a communication unit, wherein the first spring and the second spring are made of shape alloys with different rigidities, and the plunger is connected to a wire connected to the first spring according to the pressure detected by the pressure sensor. A first mode in which the rigidity of the first spring is controlled by the temperature generated by applying voltage, or the rigidity of the second spring is controlled by the temperature generated by applying voltage to the wire connected to the first spring and the second spring. According to the second mode, the lens discharge unit or the insertion penetrating unit can be placed in the eye through a minimum incision without damaging the intraocular lens, and the central server is a database that stores the data received from the communication unit. And an artificial intelligence module that performs deep learning calculations based on big data stored in the database to determine the voltage applied to the first spring and the second spring in real time, wherein the control unit detects that a specific pressure is applied from the pressure sensor. recognizes that it is falling, and stores the voltage applied to the first spring and the voltage applied to the second spring in the database of the central server in a wired or wireless manner through the communication unit, and the central server includes a plurality of intraocular lenses While communicating with the insertion mechanism, the pressure sensor recognizes that a specific pressure is applied, collects big data on the voltage applied to the first spring and the voltage applied to the second spring, and the artificial intelligence module It is characterized in that the voltage applied to the first spring and the second spring is determined in real time through deep learning calculation based on data stored in the database, and set in a new intraocular lens insertion device.

According to the present invention, when an intraocular lens is inserted into a minimized corneal incision using an intraocular lens insertion device, deformation, rotation, or damage to the intraocular lens can be prevented.

According to the present invention, the lens is inserted into the eye without being rotated or damaged, so the procedure can be performed quickly and accurately.

1 and 2 are diagrams showing an intraocular lens insertion mechanism according to an embodiment of the present invention.
Figure 3 is a perspective view showing the configuration of the plunger.
Figure 4 is a perspective view of the lens discharge portion on the tip side, which is a part of the plunger.
Figure 5 is a perspective view showing the configuration of a plunger according to an embodiment of the present invention.
Figure 6 is a diagram showing the configuration of a plunger according to an embodiment of the present invention.

In addition to the above object, other objects and features of the present invention will be clearly revealed through the description of the embodiment with reference to the accompanying drawings. Preferred embodiments of the present invention will be described in detail with reference to the attached drawings. In describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, the intraocular lens insertion device 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying FIGS. 1 to 6.

1 and 2 are diagrams showing an intraocular lens insertion device 1 according to an embodiment of the present invention.

Referring to Figures 1 and 2, the intraocular lens insertion device 1 according to an embodiment of the present invention includes a main body 100 and a plunger 200.

The main body 100 is formed in a cylindrical shape with a distal end 110 inserted into an incision hole formed in the eye tissue and a receiving portion 130 capable of receiving and disposing the lens 135 within the eye.

The plunger 200 is press-fitted into the main body 100 and pressurizes the intraocular lens 135 stored in the receiving portion 130 at its tip, thereby moving the intraocular lens 135 within the main body 100. It is moved and released from the tip 110 into the eyeball.

The receiving part 130 is provided with a mounting part (not shown) for fixing the intraocular lens 135 mounted from the outside within the main body 100, and the mounting part (not shown) holds the intraocular lens 135. It consists of a clamper (not shown) that prevents it from rotating.

The receiving part 130 is provided with a mounting part (not shown) for fixing the intraocular lens 135 mounted from the outside within the main body, and the mounting part prevents the intraocular lens 135 from rotating. It consists of a clamper (not shown).

This clamper can regulate the initial position and posture of the intraocular lens 135 by being mounted on the housing unit 130 from the outside in a state in which the intraocular lens 135 is slightly deformed within the main body 100.

The intraocular lens 135 is set in the storage unit 130 and then shipped and sold. Additionally, when in use, the user presses the plunger 200 into the distal end 110 of the main body 100.

Accordingly, the intraocular lens 135 is pressed by the plunger 200 and the intraocular lens 135 is extruded from the distal end 110. Meanwhile, the main body 100 and the plunger 200 are made of a resin material such as polypropylene. Polypropylene has a proven track record in medical devices and is a highly reliable material, including chemical resistance.

The intraocular lens 135 is formed of a lens body having a predetermined refractive power and two whisk-shaped support portions formed on the lens body to maintain the lens body within the eyeball. The lens body is formed of a flexible resin material. That is, various lens materials such as collamer, hydrophobic acrylic, hydrophilic acrylic, PEG-PEA/HEMA/styrene copolymer, polymethyl methacrylate (PMMA), and silicone can be used for the lens body.

Since the intraocular lens 135 is deployed by being inserted into the eye through a minimal incision, it must be prevented from being damaged when inserted into the eye. Therefore, the pressure inserted into the eye must be appropriately applied. To this end, an appropriate force must be applied to the plunger 200, as described later.

Figure 3 is a perspective view showing the configuration of the plunger 200. Figure 4 is a perspective view of the lens discharge portion 210 on the tip side, which is a part of the plunger 200.

Referring to Figures 3 and 4, the plunger 200 has a front-to-back length slightly larger than that of the main body 100, and includes a lens discharge portion 210 formed at the front end and an insert formed at the rear end of the lens discharge portion 210. It consists of a penetrating part 220.

The lens discharge portion 210 is formed at the tip of the plunger 200 and directly contacts the intraocular lens 135 to direct the intraocular lens 135 to the tip 110 of the main body 100. emits

The insertion penetration part 220 has a diameter set to be smaller than the diameter of the through hole of the main body 100 and can move forward and backward within the main body 100, and is a pressure plate that widens in the up and down or left and right directions at the rear end. Part 230 is formed.

Specifically, the insertion penetration portion 220 has an overall +-shaped cross section, and its left-right and vertical dimensions are set to be slightly smaller than the through-hole of the main body 100. In addition, at the rear end of the insertion penetrating portion 220, a disk-shaped pressure plate portion 230 is formed that expands in the up, down, left, and right directions.

As described above, since the intraocular lens 135 is inserted and deployed within the eye through a minimal incision, it must be prevented from being damaged when inserted into the eye. Therefore, the pressure inserted into the eye must be appropriately applied. Accordingly, the force applied by the user to the plunger 200 can be appropriately adjusted to prevent damage to the intraocular lens 135 when the intraocular lens 135 is released through the distal end 110.

The density of PMMA, a representative material of the intraocular lens 135, is 1.17-1.20 g/cm3, which is less than half that of glass. Additionally, PMMA has a higher impact strength than glass and polystyrene, but significantly lower than polycarbonate and some engineering polymers. Since the material of the intraocular lens 135 is weak, the force of the plunger 200 in direct contact must be appropriately limited in order to release the intraocular lens 135 without damage.

When inserting the intraocular lens 135 into the eye using the intraocular lens insertion device 1, the distal end 110 of the main body 100 is inserted into the incision made in the eye tissue.

At this time, in the present invention, the incision window can be minimized and the incision made. In other words, the tip of the existing insertion device for lens implantation without control over the force of the plunger 200 makes a corneal incision of 3 to 3.2 mm, but in the present invention, the pressure of the plunger 200 is finely controlled to insert an intraocular lens. Because the movement of (135) can be minimized, the incision area can be 1.6 to 2 mm.

Here, since the distal end 110 has an oblique opening shape, it can be easily inserted into the incision window. Then, after inserting the distal end 110 into the incision, the user in this state hooks the index or middle finger on the hold part 140 of the main body 100 and presses the pressure plate part 230 of the plunger 200 with the thumb or palm. ) to press the plunger 200 into the main body 100. Accordingly, as the plunger 200 advances, the intraocular lens 135 moves toward the distal end 110.

Then, when the intraocular lens 135 is press-fitted by the plunger 200 and moves forward within the main body 100, the intraocular lens 135 is deformed according to a change in the cross-sectional shape of the through hole of the distal end 110. Then, the intraocular lens 135 is extruded from the distal end 110 of the main body 100 into the eyeball in a deformed state.

Referring to FIG. 4, the lens discharge unit 210 has a first spring 211 and a fixing part 214 that contains a shock absorbing material 212 capable of absorbing shock inside the first spring 211. ) and a discharge part 215, the fixing part 214 and the discharge part 215 are assembled together, and the first spring 211 and the shock absorbing material 212 are together with the fixing part 215. It is accommodated within (214) and the discharge portion 215, and is assembled by combining the first engaging protrusion 2141 of the fixing portion 214 and the second engaging protrusion 2151 of the discharge portion 215. .

At the center of the surface where the fixing part 214 and the discharge part 215 are joined, there is a hole for the discharge part 215 to pass through a protruding portion for pushing out the lens 135 within the eyeball. Since the through hole of the fixing part 214 is slightly larger than the circumference of the discharge part 215, the discharge part 215 can reciprocate through the through hole of the fixing part 214.

A first engaging protrusion 2141 is formed to extend around the through hole of the fixing part 214 to engage with a second engaging protrusion 2151 extending beyond the circumference of the protruding portion of the discharge part 215.

The shock absorbing material 212 is intended to solve the disadvantage that when only the first spring 211 made of metal or plastic is used alone, the spring 211 may become unstable due to a rapid buffering action.

In other words, the load received by the first spring 211 is transferred to the first spring 211 by slowly contracting and restoring the shock absorbing material 212 using the quick buffering control and the characteristics (damping) of the shock absorbing material 212. (211) Safety can be ensured by dispersing the shock absorbing material 212 provided inside.

The insertion penetrating portion 220 is built into the main body 100 together with the second spring 250, and penetrates the second spring 250 along the inner peripheral surface of the second spring 250. The part 220 penetrates, one end of the second spring 250 is caught at the end of the narrow inner surface of the main body 100, and the other end of the second spring 250 is formed in the hold part 140. It is caught on the second spring engaging portion 145.

When a user presses the pressure plate 230 with his or her finger on the hold portion 140, the discharge portion 215 of the lens discharge portion 210 is inside the eyeball stored in the lens storage portion 130. The lens 135 is discharged to the distal end 110, and at the same time, the second spring 250 is extended to position the intraocular lens 135 within the eyeball without damaging it.

In this way, when the user presses the plunger 200, the lens discharge part 210 and the insertion penetration part 220 that make up the plunger 200 can press the intraocular lens 135 with appropriate strength, so that it is inserted into the eyeball. The lens 135 can be inserted into the eye through a minimal incision without being damaged or rotated.

Figure 5 is a perspective view showing the configuration of the plunger 200 according to an embodiment of the present invention.

The plunger 200 according to an embodiment of the present invention may further include a control unit 500, a pressure sensor 510, and a communication unit 520, and the plunger 200 may communicate through the communication unit 520. An external central server 600 may be included. Here, the central server 600 may include a database 610 and an artificial intelligence module 620.

The pressure sensor 510 detects the amount of pressure applied to the lens 135 within the eye from the lens discharge unit 210.

The first spring 211 and the second spring 250 are made of shape alloys with different rigidities, and the control unit 500 controls the plunger 200 to adjust the pressure and speed detected by the pressure sensor 510. Accordingly, the first mode or the first spring 211 and the second spring ( According to the second mode that controls the stiffness of the second spring 250 according to the temperature generated by applying voltage to the wire connected to the wire connected to the lens 250, the lens discharge unit 210 or the insertion penetration unit 220 It can also be placed within the eye with minimal incision without damaging the inner lens 135.

At this time, the control unit 500 recognizes that a specific pressure is applied at the pressure sensor 510, and detects the voltage applied to the first spring 211 and the second spring (211) in a wired or wireless manner through the communication unit 520. The voltage applied to 250 is stored in the database 610 of the central server 600.

In this way, the central server 600 communicates with a plurality of intraocular lens insertion devices 1, recognizes that a specific pressure is applied to the pressure sensor 510, and determines the voltage applied to the first spring 211 and Big data on the voltage applied to the second spring 250 is collected, and the artificial intelligence module 620 performs deep learning calculations based on the data stored in the database 610 to determine the first spring 211 and the first spring 211. 2 By detecting the voltage applied to the spring 250 in real time, faster setting of the new intraocular lens insertion device (1) is possible.

Figure 6 is a diagram showing the configuration of the plunger 200 according to an embodiment of the present invention.

Referring to FIG. 6, the plunger 200 is formed on one end of the second spring engaging portion 145 and may further include an elastic ring 2000 in contact with the second spring 250 in the axial direction. .

The elastic ring 2000 is formed with elastic protrusions 2100 curved in an arc shape from the outside of the elastic ring 2000 to the inside at equal intervals, and is connected to the second spring 250 in the axial direction to form a plunger 200. ) can be further absorbed.

As described above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , those skilled in the art can make various modifications and variations from this description.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and the scope of the patent claims described below as well as all things that are equivalent or equivalent to the scope of the claims will be said to fall within the scope of the spirit of the present invention. .

1: Intraocular lens insertion device
100: body
110: tip
140: Hold part
145: Second spring engaging portion
200: Plunger
211: first spring
212: Shock absorption material
230: pressure plate
250: second spring

Claims (3)

A body formed in a cylindrical shape having a distal end inserted into an incision port formed in the eye tissue and a receiving part capable of storing and disposing the lens within the eye; and
a plunger that presses the intraocular lens press-fitted into the main body and stored in the storage unit from its tip, thereby moving the intraocular lens within the main body and discharging it into the eye from the distal end; and
The main body has the tip disposed at one end, and a hold part at the other end that allows the user to fix the main body when the plunger is inserted into the main body by hooking the user's index or middle finger;
The plunger,
a lens discharge portion formed at the tip of the plunger and directly contacting the intraocular lens to discharge the intraocular lens to the distal end of the main body; and
an insertion penetrating portion whose diameter is set to be smaller than the diameter of the through hole of the main body so as to be able to advance or retreat within the main body, and which is formed at the rear end with a pressure plate portion that widens in the up and down or left and right directions;
Including,
The lens discharge part is composed of a first spring and a fixing part and a discharge part containing a shock absorbing material capable of absorbing shock inside the first spring, and the fixing part and the discharge part are assembled together,
The first spring and the shock absorbing material are accommodated together in the fixing part and the discharge parts, and are assembled by combining the first engaging protrusion of the fixing part and the second engaging protrusion of the discharging part,
The insertion penetration part is built into the main body together with a second spring, and the insertion penetration part penetrates inside the second spring along the inner peripheral surface of the second spring,
One end of the second spring is caught on an end of the narrow inner surface of the main body, and the other end of the second spring is caught on a second spring engaging portion formed in the hold portion,
When a user places a finger on the hold portion and presses the pressure plate, the discharge portion of the lens discharge portion discharges the intraocular lens stored in the storage portion to the distal end, and at the same time, the second spring extends to press the pressure plate. A minimally invasive intraocular lens insertion device, characterized in that it is placed within the eye without damaging the inner lens.
delete According to paragraph 1,
The plunger,
a control unit capable of controlling voltage input to the first spring and the second spring;
A pressure sensor that detects the amount of pressure applied to the lens within the eye from the lens discharge unit; and
The voltage input to the first spring and the second spring measured by the control unit and the amount of pressure applied to the intraocular lens from the lens discharge unit detected by the pressure sensor are transmitted to the central server, and the central server a communication unit that receives an output value from;
It further includes,
The control unit,
The first spring and the second spring are made of shape alloys with different rigidities, and the plunger is adjusted to the temperature generated by applying a voltage to a wire connected to the first spring according to the pressure detected by the pressure sensor. 1 According to the first mode that controls the stiffness of the spring or the second mode that controls the stiffness of the second spring by the temperature generated by applying voltage to the wire connected to the first spring and the second spring, the lens is discharged. The portion or the insertion penetrating portion can be placed within the eye through a minimal incision without damaging the intraocular lens,
The central server is,
a database storing data received from the communication unit; and
An artificial intelligence module that performs deep learning calculations based on data stored in the database to determine the voltage applied to the first spring and the second spring in real time;
Including,
The control unit,
Recognizes that a specific pressure is applied by the pressure sensor, and stores the voltage applied to the first spring and the voltage applied to the second spring in the database of the central server in a wired or wireless manner through the communication unit,
The central server is,
While communicating with a plurality of intraocular lens insertion devices, the pressure sensor recognizes that a specific pressure is applied, collects big data on the voltage applied to the first spring and the voltage applied to the second spring, and Characterized in that the artificial intelligence module performs deep learning calculations based on data stored in the database to determine the voltage applied to the first spring and the second spring in real time and quickly sets it in a new intraocular lens insertion device. An incision intraocular lens insertion device.