KR101355598B1 - 3d implant for orbital wall and floor - Google Patents

Abstract

The present invention provides a three dimensional implant for the reconstruction of an orbital wall which comprises the following: a first surface contacting the inner wall of an eye socket; a second surface contacting the front side on the lower wall of the eye socket; and a third surface including a first connection line connected to the first surface and a second connection line connected to the second surface, and contacting the rear side on the lower wall of the eye socket.

Description

3D IMPLANT FOR ORBITAL WALL AND FLOOR}

The present invention relates to implants for orbital wall reconstruction, and more particularly to implants of three-dimensional solid structure that is inserted and fixed to the orbit when orbital wall reconstruction is performed.

Orbital wall fractures are fractures that occur in the orbital wall due to rapid increase in orbital pressure due to external impacts. Orbital wall fractures are accompanied by symptoms such as bleeding, eye movement disorders, diplopia (two objects), and ocular depression. Today, the incidence of orbital wall fractures is increasing due to increased transportation and speed, increased leisure and sports activities, and increased violence.

When orbital wall fractures occur, medication is administered for about two weeks until bleeding and edema subside. After oral medication, orbital wall ocular depression, severe fracture, diplopia, or severe eye movement impairment, orbital wall reconstruction is performed. In orbital wall reconstruction, the dislocated muscle or tissue is first restored to its original position, and then the implant is inserted and fixed in the orbit. The implant replaces the orbital wall until the fractured orbital wall is restored, or permanently replaces the irreparable orbital wall.

Korean Patent No. 1027252 discloses an implant used for orbital wall reconstruction. The implant comprises a polyethylene matrix and a metal mesh embedded in the matrix. The polyethylene matrix covers the metal mesh while filling the space of the metal mesh, which maintains the shape of the displaced implant.

When performing orbital wall reconstruction using the implant of Korean Patent No. 1027252, the operator first deforms the implant to a desired shape while bending the implant by hand, wherein the implant is deformed due to the rigidity of the metal mesh. Form will be maintained. The operator then inserts the deformed implant into the orbit and secures it.

 According to the implant disclosed in Korean Patent No. 1027252, the operator must deform the implant into an appropriate shape in the middle of performing orbital wall reconstruction. Therefore, the implant of Korean Patent No. 1027252 not only troubles the operator but also increases the time taken for orbital wall reconstruction.

Accordingly, the present invention is to provide a three-dimensional implant implant for reconstructing the orbital wall does not need to be modified by the operator in the process of orbital wall reconstruction.

The present invention includes a first surface to be in contact with the orbital inner wall; A second surface to be in contact with the front portion of the orbital lower wall; And a third surface having a first connection side connected to the first surface and a second connection side connected to the second surface and being in contact with a rear portion of the lower orbital wall. 3D stereoscopic implant for orbital wall reconstruction including a To provide.

The front side of the first surface, the first connection side, the second connection side, and the inner side of the second side meet at one contact to be located immediately behind the fistula, the rear end of the first connection side The outer side of the third surface connecting the outer end of the second connecting side is located in front of the passage through which the optic nerve and muscle pass.

The upper side of the first surface facing the first connection side has a curved shape having an angle of at least 120 degrees and the maximum 160 degrees with respect to the third surface, and the front side of the second surface facing the second connection side is the first side. It is a curved shape with angles of at least 130 degrees and at most 170 degrees with respect to three sides.

In this case, the upper side of the first surface has an angle of 160 degrees at the central portion, the angle of 120 degrees at at least one of the front and rear ends, the front side of the second surface has the angle of 170 degrees at the central portion and the inner end At the outer end, the angle is 130 degrees.

A fixing tab having a screw through hole is connected to an upper side of the first surface and a front side of the second surface. The fixing tab is made of the same material as the first, second and third surfaces.

The present invention has a first surface which is in contact with the orbital inner wall, a second surface which is in contact with the front part of the orbital lower wall, and a third surface which is in contact with the rear part of the orbital lower wall. Therefore, the present invention can be inserted directly into the orbit without having to be modified by the operator in the process of orbital wall reconstruction.

In addition, the present invention does not cover the passage and the fistula through which the optic nerve and muscle pass even when inserted into the orbit.

In addition, the present invention can be used in all adult men and women.

In addition, according to the present invention, since the fixing tab is connected to the first and second surfaces in the process of forming the first, second and third surfaces, a separate procedure for connecting the fixing tab is unnecessary.

1 is a photograph showing the structure of the orbital wall.
Figure 2 is a perspective view showing a three-dimensional three-dimensional implant implant for reconstruction of the orbital wall according to the present invention.
3 is a photograph showing a state in which the three-dimensional solid implant for orbital wall reconstruction shown in FIG. 2 is inserted into the orbit.

Hereinafter, preferred embodiments of the three-dimensional solid implant for orbital wall reconstruction according to the present invention will be described in detail with reference to the drawings. It is to be understood that the terminology or words used herein are not to be construed in an ordinary sense or a dictionary, and that the inventor can properly define the concept of a term to describe its invention in the best possible way And should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

The orbital wall will first be described with reference to FIG. 1 for easy understanding of the three-dimensional conformal implant 100 for orbital wall reconstruction according to the present invention.

The orbital wall is a bone surrounding the orbit, and as shown in FIG. 1, the orbital inner wall 10 and the orbital lower walls 20a and 20b are included, and the orbital lower walls 20a and 20b are the front portion 20a and the rear portion 20b. ). The back portion 20b of the orbital lower wall is connected to the orbital inner wall 10. And the front part 20a of the orbital wall is connected to the back part 20b of the orbital wall and is located at the entrance of the orbital wall. A fistula 30 is provided at the front of the orbital wall, and a passage 40 through which the optic nerve and the muscle passes is provided at the rear thereof. In FIG. 1, the two passages 40 are separated, but when viewed from different angles, the two passages 40 are connected to each other.

3D solid implant for reconstruction of the orbital wall according to the present invention 100 is a thin plate form inserted into the orbit to replace the orbital wall or permanently replace the orbital wall until the fractured orbital wall is restored, Figure 2 As shown in FIG. 1, the first surface 110, the second surface 120, and the third surface 130 are included.

The first surface 110 is a surface contacting the orbital inner wall 10 when the implant 100 is inserted into the orbit, and includes a front side 112, a rear side 114, and an upper side 116. The front side 112 of the first surface 110 is located at the entrance side (front) of the orbit, and the rear side 114 of the first surface 110 is located at the rear and faces the front side 112. The upper side 116 of the first surface 110 connects the upper end of the front side 112 and the upper end of the rear side 114.

The second surface 120 is a surface contacting the front portion 20a of the lower orbital wall when the implant 100 is inserted into the orbit, and includes an inner side 122, an outer side 124, and a front side 126. . The inner side 122 of the second side 120 has a rear end that meets the lower end of the front side 112 of the first side 110 at the contact point 140, and from the contact point 140 toward the entrance to the orbit (front side). Extend. The outer side 124 of the second surface 120 is positioned to face the inner side 122. The front side 126 of the second surface 120 connects the front end of the inner side 122 and the front end of the outer side 124.

The third surface 130 is a surface that is in contact with the rear portion 20b of the lower wall of the orbit when the implant 100 is inserted into the orbit, the first connection side 132, the second connection side 134, and the outer side ( 136). The first connection side 132 is connected to the first surface 110 and has a straight shape extending rearward from the contact point 140. The second connection side 134 is connected to the second surface 120 and has a straight line extending outward from the contact 140. The outer side 136 of the third surface 130 is a side connecting the rear end of the first connection side 132 and the outer end of the second connection side 134, at the rear end of the first connection side 132 It meets the lower end of the rear side 114 of the first surface 110, and meets the rear end of the outer wall 124 of the second surface 120 at the outer end of the second connection side 134.

As described above, the three-dimensional solid structure implant 100 for reconstructing the orbital wall according to the present invention has a first surface 110 which is in contact with the orbital inner wall 10, and a second surface which is in contact with the front portion 20a of the orbital wall. And a third surface 130 in contact with the rear portion 20b of the orbital lower wall. Therefore, the implant 100 can be inserted directly into the orbit without having to be deformed by the operator in the process of orbital wall reconstruction.

On the other hand, the fistula 30 is provided on the orbital wall as described above, the fistula 30 should not be covered by the implant 100 inserted into the orbit. To this end, the contact 140 is provided to be located immediately behind the fistula 30 when the implant 100 is inserted into the orbit.

In addition, the orbital wall is provided with a passage 40, which should not be covered by the implant 100 inserted into the orbit. To this end, the outer side 136 of the third surface 130 is provided to be located directly in front of the passage 40 when the implant 100 is inserted into the orbit.

Applicants have analyzed clinical data for the manufacture of three-dimensional conformal implant 100 for orbital wall reconstruction, which can be used universally for all adult men and women, and as a result, the characteristics of the implant 100 should be found. Implant 100, which can be applied to all adults regardless of race and gender, only shares the above characteristics with differences only in size. Hereinafter, the above features will be described in detail with reference to FIGS. 2 and 3.

First, the third surface 130 is almost flat, but finely convex upward from the central portion.

The first surface 110 is a curved surface convex in the whole, the upper side 116 of the first surface 110 is a curved shape convexly curved inward. Here, the upper side 116 of the first surface 110 has an angle of at least 120 degrees and at most 160 degrees with respect to the third surface 130. Specifically, the upper side 116 of the first surface 110 has a maximum angle A1 of 160 degrees at the central portion, and has a minimum angle of 120 degrees at at least one of the front and rear ends (both front or rear ends or both front and rear ends). A2, A3). 2 shows an example in which the front and rear ends of the upper side 116 have minimum angles A2 and A3. The angles A1, A2, and A3 pass through the central portion, front, and rear ends of the upper side 116, and lines 118a, 118b, and 118c perpendicular to the first connection side 132 and the third surface 130. Are measured between

The second surface 120 is basically flat, and has a curved surface that is convex downward from the outer end. Accordingly, the front side 126 of the second surface 120 extends straight outwardly and then curves upward from the outer end. In this case, the front side 126 of the second surface 120 has an angle of at least 130 degrees and at most 170 degrees with respect to the third surface 130. Specifically, the front side 126 of the second surface 120 has a maximum angle B1 of 170 degrees at the central portion and the inner end, and has a minimum angle B2 of 130 degrees at the outer end. These angles B1 and B2 pass through the central portion and the inner end of the front side 126, between the line 128a and the third surface 130 perpendicular to the second connection side 134, and the front side 126. It is measured between the line 128b perpendicular to the second connection side 134 and the third surface 130 while passing through the outer end of the side surface.

The three-dimensional stereoscopic implant 100 for reconstructing the orbital wall is inserted into the orbit and replaces the orbital wall until the fractured orbital wall is restored. The implant 100 is manufactured by injection molding a biodegradable material when the orbital wall is replaced until the orbital wall is restored, and by injection molding a biocompatible material when the orbital wall is permanently replaced.

The biodegradable materials include PLA (poly (lactic acid)), PLLA (poly (L-lactic acid)), PLDLA (poly (L / D-lactic acid)), PGA (poly (glycolider) or poly (glycolic acid) )), Biodegradable organic polymers such as PLGA (poly (lactic-co-glycolic acid)), PLC (poly (camprolactone)), betatipi (β-TCP, β-tricalcium phosphate), magnesium (Mg, magnesium) Biodegradable minerals such as) may be used. As the biocompatible material, biocompatible minerals such as hydroxyapatite may be used.

On the other hand, the implant 100 is to be fixed after being inserted into the orbit, may include a fixing tab. The fixing tab includes a first fixing tab 150 connected to the upper side 116 of the first surface 110 and a second fixing tab 160 connected to the front side 126 of the second surface 120. The first fixing tab 150 and the second fixing tab 160 have a plurality of screw through holes 152 and 162 arranged along their longitudinal direction, and the screw through holes of the first fixing tab 150 are provided. Screws (not shown) to be fastened to the nasal bones pass through the fields 152, and screws (not shown) to be fastened to the cheekbones pass through the screw through holes 162 of the second fixing tab 150.

The fixing tabs 150 and 160 are made of the same material as the first surface 110, the second surface 120, and the third surface 130, in which case the surfaces 110, 120, and 130 are ejected. Since the fixing tabs 150 and 160 may be formed together when formed, a separate procedure for connecting the fixing tabs 150 and 160 is unnecessary.

Although not shown, a plurality of holes having a diameter within a range of 0.5 mm to 3.0 mm may be provided in at least one of the surfaces 110, 120, and 130 to allow rapid regeneration of the fractured orbital wall. .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: three-dimensional solid implant for orbital wall reconstruction
110: first side 112: front side of the first side
114: rear side of first side 116: upper side of first side
120: second surface 122: the inner side of the second surface
124: outer side of the second side 126: front side of the second side
130: the third page 132: first connection side
134: second connection side 136: the outer side of the third surface
150: first fixing tab 160: second fixing tab

Claims (7)

A first surface to be in contact with the orbital inner wall;
A second surface to be in contact with the front portion of the orbital lower wall; And
And a third surface having a first connection side connected to the first surface and a second connection side connected to the second surface and coming into contact with a rear portion of the lower orbital wall. 3. The method of claim 1,
The front side of the first surface, the first connection side, the second connection side, and the inner side of the second surface is a three-dimensional stereoscopic reconstruction for the orbital wall that meets at one contact point to be located immediately behind the fistula Structural implants. The method of claim 1,
The outer side of the third surface connecting the rear end of the first connecting side and the outer end of the second connecting side is a three-dimensional implant for reconstruction of the orbital wall is located just in front of the passage through the optic nerve and muscle. The method of claim 1,
The upper side of the first surface facing the first connection side has a curved shape having an angle of at least 120 degrees and the maximum 160 degrees with respect to the third surface, and the front side of the second surface facing the second connection side is the first side. Three-dimensional solid implant for orbital wall reconstruction, with curvilinear angles of at least 130 degrees and at most 170 degrees with respect to three sides. 5. The method of claim 4,
The upper side of the first surface has an angle of 160 degrees at the central portion, the angle of 120 degrees at at least one of the front and rear ends, the front side of the second surface has the angle of 170 degrees at the central portion and the inner end, the outside A three-dimensional solid implant for orbital wall reconstruction having an angle of 130 degrees at the end. 5. The method of claim 4,
3D stereoscopic implant for orbital wall reconstruction, wherein a fixing tab having a screw through hole is connected to an upper side of the first surface and a front side of the second surface. The method according to claim 6,
The fixing tab is a three-dimensional three-dimensional implant implant for reconstruction of the orbital wall made of the same material as the first, second and third surfaces.

Images