KR102412068B1 - Implant for intervertebral disk using bone fusion member - Google Patents

Abstract

A bone fusion member and an intervertebral body replacement implant having the same are provided. The osseointegration member according to an embodiment of the present invention is a osseointegration member for replacement of the intervertebral body that is embedded in the space between the adjacent first and second vertebrae, and includes a body made of a bioactive crystallized glass material. Here, the body has a shape corresponding to the surface shape of each of the first vertebra and the second vertebra, and the body is coupled through a plate and a buffer member for fixing to the first vertebra and the second vertebra, and a groove for coupling the buffer member An additional is provided on the side of the body.

Description

Intervertebral body replacement implant having a bone fusion member {Implant for intervertebral disk using bone fusion member}

The present invention relates to an implant for replacement of an intervertebral body having a osseointegration member, and more particularly, to an implant for replacement of an intervertebral body having a osseointegration member that is easy to operate and can improve fusion with bone and mechanical stability.

In general, vertebral intervertebral cartilage and/or vertebrae of the vertebrae may be dislocated or damaged due to trauma, illness, degenerative disease, or prolonged wear and tear. In order to alleviate the disease caused by such dislocation or damage, the intervertebral cartilage is replaced with an implant such as a spacer or cage.

However, the conventional implant for an intervertebral body has a complicated structure because an opening for accommodating the bone graft material must be formed inside the spacer or cage in order to solve the low cohesion between the implant material and the bone, and a separate bone graft material is provided. There is a problem that the procedure is cumbersome because it has to be done.

In addition, bone grafts such as allograft bone, autograft bone, or xenograft bone, or spacers or cages composed of ceramics, polymers, metals and biomaterials do not secure mechanical stability due to low compressive strength, so there is a risk of damage during long-term use. There is this.

Moreover, in the case of the conventional standalone cage, there is a problem of anatomical mismatch between the implant and the spine of each patient because processability is not easy.

JP 2013-169465 A (Public Date 2013.09.02)

In order to solve the problems of the prior art as described above, an embodiment of the present invention is to provide an implant for replacement of an intervertebral body having an osseointegration member that is easy to operate and can improve fusion with bone and mechanical stability. .

According to one aspect of the present invention for solving the above problems, there is provided a bone fusion member for replacement of the intervertebral body embedded in the space between the adjacent first vertebra and the second vertebra. The osseointegration member for the replacement of the intervertebral body includes a body made of a bioactive crystallized glass material, the body has a shape corresponding to the surface shape of each of the first vertebra and the second vertebra, the body is the first vertebra And coupled through a plate and a buffer member for fixing to the second vertebra, a groove for coupling the buffer member is provided on the side of the body.

In an embodiment, the body may be manufactured by CAD/CAM or 3D printing based on the patient's medical image information.

In one embodiment, the body may be provided with a plurality of projections in one direction on the surface in contact with each of the first vertebra and the second vertebra.

In one embodiment, the bioactive crystallized glass material may include CaSiO ₃ , apatite, and Ca ₂ Mg(Si ₂ O ₇ ) in a weight ratio of 1: 0.7 to 1.5: 0.5 to 1.2.

According to another aspect of the present invention, the osseointegration member as described above; a plate made of titanium (Ti) and fixed to the first vertebra and the second vertebra; and a buffer member made of a polyetheretherketone (PEEK) material, disposed between the bone union member and the plate, and coupling the bone union member and the plate;

In one embodiment, the implant for replacement of the intervertebral body further comprises a first screw for coupling with the first vertebra and a second screw for coupling with the second vertebra, receiving the first screw on both sides of the plate A first accommodating hole and a second accommodating hole accommodating the second screw are provided, and a pair of guide grooves are provided at symmetrical positions of the buffer member so that the first screw and the second screw are fastened at different angles. This may be provided.

In one embodiment, the plate is provided with a pair of accommodating grooves for accommodating a locking screw for locking the first screw and the second screw in a central portion between the first accommodating hole and the second accommodating hole, One side of the pair of accommodating grooves may communicate with the first accommodating hole and the second accommodating hole.

In one embodiment, the buffer member, a pair of support for coupling to the body of the osseointegration member; And it includes a central portion for connecting the pair of support, the support portion may be inserted into the groove portion of the body of the fusion member in a fitting manner.

In one embodiment, the buffer member may be provided with fastening grooves for coupling the plate to both sides of the central portion, and the plate may be provided with fastening protrusions corresponding to the fastening grooves on both sides of the plate.

In one embodiment, the plate may be provided with at least one wedge portion at a position symmetrical to each other on a surface in contact with the first vertebra and a surface in contact with the second vertebra.

The osseointegration member and the intervertebral body replacement implant having the same according to an embodiment of the present invention can improve fusion with bone and mechanical stability by using a material having high cohesiveness and strength with bone.

In addition, the present invention can further promote fusion with the bone by increasing the area of the bone union, and more stably fix the position between the bones.

In addition, according to the present invention, since a shape corresponding to the surface of the patient's vertebra can be manufactured based on the patient's image information, the patient's anatomical compatibility can be improved, thereby improving the reliability of the replacement function of the intervertebral body.

In addition, the present invention is provided with a buffer member between the brittle osseointegration member and the high-strength plate to suppress the breakage of the osseointegration member by an external force, it is possible to further improve the mechanical stability.

In addition, the present invention is provided with a wedge portion coupled to one side of the vertebra to the plate, so that the plate is directly fixed to the vertebra, it is possible to prevent distortion of the implant that may occur according to the movement of the patient.

In addition, the present invention can secure the angle of the screw for coupling with the bone by providing a guide groove in the buffer member between the plate and the bone fusion member, it is possible to further improve the ease of the procedure.

In addition, since the present invention does not require a separate bone graft material, it is easy to perform the procedure without the hassle of applying a bone graft material during the procedure, and the procedure time can be shortened, thereby improving convenience for patients and medical staff.

1 is a perspective view of an intervertebral body replacement implant according to an embodiment of the present invention;
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is a perspective view of the osseointegration member of Figure 1,
Fig. 4 is a perspective view of the plate of Fig. 1;
Figure 5 is a perspective view of the buffer member of Figure 1;
Figure 6 is a perspective view of a state in which the screw is coupled to the implant of Figure 1, and,
7 is a view showing a state of use of the implant for replacement of the intervertebral body according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are given to the same or similar components throughout the specification.

Hereinafter, an intervertebral body replacement implant according to an embodiment of the present invention will be described in more detail with reference to the drawings.

Referring to FIG. 1 , an intervertebral body replacement implant 100 according to an embodiment of the present invention includes a bone fusion member 110 , a plate 120 , and a buffer member 130 .

This intervertebral body replacement implant 100 is to replace an intervertebral body such as intervertebral cartilage, and is embedded in the space between adjacent vertebrae as shown in FIG. 7 . Here, the intervertebral body replacement implant 100 may be coupled to the first vertebra 11 by a first screw 140a and coupled to the second vertebra 12 by a second screw 140b.

At this time, the bone fusion member 110 is embedded between both sides of the first vertebra 11 and the second vertebra 12, and the plate 120 is at one end of the first vertebra 11 and the second vertebra 12. can be fixed.

The bone union member 110 may include a body 110a made of a bioactive crystallized glass material. Here, the bioactive crystallized glass material may include CaSiO ₃ . In addition, the bioactive crystallized glass material is Ca ₁₀ (PO ₄ ) ₆ A (here, A is an oxygen atom) and Ca ₁₀ (PO ₄ )6B ₂ (here, B is a hydroxyl group, a fluorine atom or a chlorine atom. ) apatite and Ca ₂ Mg (Si ₂ O ₇ ) including at least one selected from among them may include. Here, the active crystallized glass material may include CaSiO ₃ , apatite, and Ca ₂ Mg(Si ₂ O ₇ ) in a weight ratio of 1: 0.7 to 1.5: 0.5 to 1.2.

Since such bioactive crystallized glass material has bone union characteristics and great strength, it can effectively replace the tissue defect in the living body when implanted in vivo.

Therefore, since there is no need to provide a separate bone graft material, it is easy to perform the procedure without the hassle of applying the bone graft material during the procedure, and the procedure time can be shortened, thereby improving convenience for patients and medical staff.

The body 110a may have a shape corresponding to the surface shape of each of the first vertebra 11 and the second vertebra 12 . For example, the body 110a may be manufactured by CAD/CAM or 3D printing based on the patient's medical image information. The body 110a may be formed so that the surface in contact with the first vertebra 11 and the second vertebra 12 is inclined.

Through this, the bone fusion member 110 can be custom-made to be substantially similar to or identical to the shape of the patient's vertebrae, thereby minimizing anatomical mismatch between the vertebrae.

Here, the body 110a may be provided with grooves 111a, 111b, and 111c along the side thereof, as shown in FIGS. 2 and 3 . At this time, the support portion 131 of the buffer member 130 may be inserted into the groove portions 111a on both sides of the body 110a.

In addition, the central portion 132 of the buffer member 130 is inserted into the groove portion 111b in the front of the body 110a, and the end of the support portion 131 of the buffer member 130 is inserted into the rear groove portion 111c. can be That is, the body 110a may be formed in a shape in which the buffer member 130 is inserted into the grooves 111a, 111b, and 111c to surround it.

Thereby, the bone fusion member 110 may be coupled to the plate 120 for fixing to the first vertebra 11 and the second vertebra 12 through the buffer member 130 .

In addition, a plurality of projections 112 in one direction may be provided on the upper and lower surfaces of the body 110a, that is, the surfaces in contact with each of the first vertebrae 11 and the second vertebrae 12 . Each of these protrusions 112 is provided with a constant thickness and length from the surface of the body 110a, and may be provided at regular intervals from each other.

Through this, by increasing the fusion area joined to the first vertebra 11 and the second vertebra 12, the fusion with the bone can be further promoted, and the fusion with the first vertebra 11 and the second vertebra 12 is increased. It is possible to more stably fix the position of the body 110a between the bones by the protrusion 112 being.

In addition, the protrusion 112 and the first vertebra 11 and the second vertebra 12 may improve the fixing force of the body 110a by mutual frictional coupling.

The plate 120 includes a body 121 made of titanium (Ti), and is fixed to the first vertebrae 11 and the second vertebrae 12 by first screws 140a and second screws 140b. .

The plate 120 may be provided with a first accommodating hole 122a for accommodating the first screw 140a and a second accommodating hole 122b for accommodating the second screw 140b on both sides of the body 121 . have. The first accommodating hole 122a and the second accommodating hole 122b may be inclined at different angles from each other. That is, as shown in FIG. 7 , since the first screw 140a and the second screw 140b are coupled to the first vertebra 11 and the second vertebra 12 at different angles from each other, the first The first accommodating hole 122a and the second accommodating hole 122b may be provided to be inclined so that the screw 140a and the second screw 140b are inserted at different angles to the plate 120 .

In addition, the first accommodating hole 122a and the second accommodating hole 122b may optionally have a thread for fastening the first screw 140a and the second screw 140b therein.

In addition, the plate 120 accommodates a lock screw 129 for locking the first screw 140a and the second screw 140b in the central portion between the first accommodation hole 122a and the second accommodation hole 122b. A pair of receiving grooves 124 may be provided.

Here, the pair of accommodating grooves 124 are provided independently from each other by a partition wall, and a communication part 125 communicating with the first accommodating hole 122a and the second accommodating hole 122b is provided on one side thereof. can be That is, the pair of accommodating grooves 124 and the first accommodating hole 122a and the second accommodating hole 122b are provided to overlap each other, so that a part thereof communicates with each other.

Through this, the head of the locking screw 129 in the communication part 125 blocks a part of the first accommodating hole 122a and the second accommodating hole 122b, so that the first screw 140a and the second screw ( 140b) may be locked so that it does not escape to the outside.

In this case, the locking screw 129 may include a first part 129a having a part inwardly recessed on one side. Here, the first portion 129a may be formed in a shape corresponding to the communication portion 125 . That is, when the locking screw 129 is integrally provided with the plate 120, by rotating the first portion 129a to be positioned in the communication portion 125, the first accommodating hole 122a and the second accommodating hole ( 122b) is completely opened without being blocked by the locking screw 129, so that the first screw 140a and the second screw 140b can be inserted into the first receiving hole 122a and the second receiving hole 122b. have.

In addition, the plate 120 may be provided with at least one wedge portion 123 on the surface in contact with the first vertebra 11 and the surface in contact with the second vertebra 12 . That is, as shown in FIGS. 2 and 4 , the plate 120 has at least one wedge at a position symmetrical to the lower surface of the first accommodating hole 122a and the upper surface of the second accommodating hole 122b. A unit 123 may be provided.

Here, the wedge portion 123 may be provided at a position opposite to the fastening direction of the first screw 140a and the second screw 140b. That is, as shown in Figure 6, when the first screw (140a) is coupled to the upper side of the bone union member (110), the wedge portion 123 is disposed below the first receiving hole (122a), the second screw When the (140b) is coupled to the lower side of the bone fusion member 110, the wedge 123 may be disposed on the upper side of the second receiving hole (122b).

However, it goes without saying that the formation position of the wedge portion 123 may be changed according to the fastening direction of the first screw 140a and the second screw 140b.

When a plurality of such wedge portions 123 are provided, they may be disposed to be spaced apart from each other at regular intervals, and one end may be formed with a sharp tip so as to be fixed to the first vertebra 11 or the second vertebra 12 .

Through this, it is possible to suppress or minimize the torsion of the intervertebral body replacement implant 100 that may occur according to the movement of the patient, thereby further improving structural stability, and thus, the service life of the intervertebral body replacement implant 100 . can be extended.

In addition, the plate 120 may be provided with fastening protrusions 127 corresponding to the fastening grooves 135 of the buffer member 130 on both sides. The fastening protrusion 127 may be formed toward the rear side of the plate 120 , that is, toward the buffer member 130 . Here, the fastening protrusion 127 may be provided with one end bent inward of the body 121 . That is, the fastening protrusion 127 may be formed in a “L” shape on the rear surface of the body 121 .

Through this, the plate 120 may be coupled to the buffer member 130 by a simple structure. For this reason, since the plate 120 can be formed to have a thin thickness, the volume of the plate 120 can be minimized to increase the volume of the bone union member 110, and thus, the fusion area with the bone can be further increased. can

The buffer member 130 is made of a polyether ether ketone (PEEK) material, and is disposed between the bone union member 110 and the plate 120 to combine the bone union member 110 and the plate 120 .

This cushioning member 130 is to separate the brittle bone fusion member 110 and the plate 120 of metal material from each other. When the bone fusion member 110 and the plate 120 are in direct contact, the human body or the first vertebra (11) and the second vertebra 12 can be prevented from being damaged by an external force applied. Here, the buffer member 130 may include a pair of support portions 131 and a central portion 132 .

A pair of support portions 131 may be inserted into and coupled to the groove portion 111a of the body 110a to be coupled to the body 110a of the bone fusion member 110 . In this case, one end of the support part 131 may include a bent part 133 bent inward. Here, the bent portion 133 may be inserted and coupled to both sides of the groove portion (111c) of the body (110a) of the bone union member (110).

The central portion 132 connects between the pair of support portions 131 , and may be inserted and coupled to the groove portion 111b of the body 110a of the bone fusion member 110 .

Through this, the buffer member 130 is inserted into the support portion 131 and the central portion 132 in the groove portions (111a, 111b, 111c) of the bone fusion member 110, respectively, and at this time, it may be inserted and coupled in a fitting manner.

Here, on both sides of the central portion 132, a pair of guide grooves 134 so that the first screw 140a and the second screw 140b are coupled to the first vertebra 11 and the second vertebra 12 at a predetermined angle. This may be provided. That is, since the first screw 140a and the second screw 140b are obliquely coupled to the first vertebra 11 and the second vertebra 12 as shown in FIG. 7 , the rear of the plate 120 . It may interfere with the central portion 132 of the buffer member 130 disposed in the.

To solve this, a pair of guide grooves 134 may be formed in communication with the first accommodating hole 122a and the second accommodating hole 122b. In this case, the pair of guide grooves 134 may be disposed at positions symmetrical to each other on both sides of the central portion 132 .

That is, the guide groove 134 corresponding to the first accommodating hole 122a is disposed on the upper side of the central part 132 , and the guide groove 134 corresponding to the second accommodating hole 122b is located on the lower side of the central part 132 . can be placed in

Here, the guide groove 134 may be provided at the same position as the fastening direction of the first screw 140a and the second screw 140b. That is, as shown in Figure 6, when the first screw (140a) is coupled to the upper side of the bone union member (110), the guide groove (134) corresponding to the first receiving hole (122a) is the upper side in the central portion (132) When the second screw 140b is coupled to the lower side of the bone fusion member 110 , the guide groove 134 corresponding to the second receiving hole 122b may be disposed on the lower side in the central portion 132 .

However, the shape of the first accommodating hole 122a, the second accommodating hole 122b, and the pair of guide grooves 134 depends on the fastening direction or fastening method of the first screw 140a and the second screw 140b. It is of course subject to change.

The guide groove 134 may be provided in an upper or lower open form in the central portion 132 . For example, the guide groove 134 may be provided in a hemispherical shape.

Through this, a variable coupling angle of the first screw 140a and the second screw 140b coupled to the first vertebra 11 and the second vertebra 12 can be easily secured.

In addition, the buffer member 130 may be provided with fastening grooves 135 for coupling the plate 120 to both sides of the central portion 132 . The fastening groove 135 may be provided in a shape corresponding to the fastening protrusion 127 of the plate 120 .

For example, the fastening groove 135 may be formed inwardly from one side of the support part 131 on both sides of the central part 132 as shown in FIGS. 2 and 5 . Here, the lower end 135a of the fastening groove 135 may be formed to extend from the support 131 so that the lower surface of the fastening protrusion 127 of the plate 120 is supported.

Through this, the plate 120 is coupled to the front surface of the buffer member 130 and the bone fusion member 110 is coupled to the rear surface of the buffer member 130, so that the plate 120 and the bone union member 110 are spaced apart at regular intervals. can be stably bound.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same spirit. , changes, deletions, additions, etc. may easily suggest other embodiments, but this will also fall within the scope of the present invention.

100: implant for replacement of the intervertebral body 110: osseointegration member
110a: body 111: groove
112: protrusion 120: plate
121: body 122a: first receiving hole
122b: second receiving hole 123: wedge portion
124: receiving groove 125: communication part
126: screw groove 127: fastening projection
129: lock screw
129a: first part 130: buffer member
131: support part 132: central part
133: bent part 134: guide groove
135: fastening groove 140a: first screw
140b: second screw

Claims (10)

An intervertebral body replacement implant having a osseointegration member embedded in the space between the adjacent first and second vertebrae,
a body made of a bioactive crystallized glass material, wherein the body has a shape corresponding to the surface shape of each of the first vertebra and the second vertebra, and the body is fixed to the first vertebra and the second vertebra a bone union member coupled through a plate and a buffer member for, and provided with a groove portion on a side surface of the body for coupling the buffer member;
a plate made of titanium (Ti) and fixed to the first vertebra and the second vertebra; and
A buffer member made of a polyetheretherketone (PEEK; Polyetheretherketone) material, disposed between the bone union member and the plate, and coupling the bone union member and the plate;
It further comprises a first screw for coupling with the first vertebra and a second screw for coupling with the second vertebra, and accommodates a first accommodating hole for accommodating the first screw and the second screw on both sides of the plate. a second receiving hole is provided, and a pair of guide grooves are provided at symmetrical positions of the buffer member so that the first screw and the second screw are fastened at different angles,
The plate is provided with a pair of accommodating grooves for accommodating a locking screw for locking the first screw and the second screw in a central portion between the first accommodating hole and the second accommodating hole, and the pair of accommodating grooves One side of the groove communicates with the first accommodating hole and the second accommodating hole, and the locking screw includes a first part partially recessed inward on one side, and the first part is formed in a shape corresponding to the communicating part. It is positioned so that it does not interfere when the first screw and the second screw are fastened, and is positioned so that it does not fall out after fastening,
The buffer member, a pair of support for coupling to the body of the osseointegration member; and a central portion connecting the pair of supports, wherein the support portion is inserted and coupled to the groove portion of the body of the bone fusion member in a fitting manner,
The buffer member is provided with fastening grooves for coupling the plate to both sides of the central portion, and the plate is provided with fastening protrusions corresponding to the fastening grooves on both sides of the plate,
The plate is an intervertebral body replacement implant having a osseointegration member provided with at least one wedge portion at a position symmetrical to each other on a surface in contact with the first vertebra and a surface in contact with the second vertebra. According to claim 1,
The body is an implant for replacement of an intervertebral body having a osseointegration member manufactured by CAD/CAM or 3D printing based on the patient's medical image information. According to claim 1,
The body is an intervertebral body replacement implant having a osseointegration member provided with a plurality of protrusions in one direction on a surface in contact with each of the first and second vertebrae. According to claim 1,
The bioactive crystallized glass material is CaSiO ₃ , apatite, and Ca ₂ Mg(Si ₂ O ₇ ) An implant for replacement of an intervertebral body having a osseointegration member comprising a weight ratio of 1: 0.7 to 1.5: 0.5 to 1.2. delete delete delete delete delete delete

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