KR102511114B1 - Unidirectional expandable intervertebral fusion cage device - Google Patents

Abstract

The present invention relates to an unidirectional expandable intervertebral fusion cage device comprising: a first side body having a first inclined surface formed forward from the right side and a protrusion formed on the first inclined surface; and a second side body having a second inclined surface formed from the left side to the rear side and a rail formed on the second inclined surface, to which the protrusion is coupled, wherein when the first side body pushes from behind and moves, the first side body moves forward as the protrusion moves along the rail with the first inclined surface in contact with the second inclined surface and the second side body is pushed to the right and moves. According to the present invention, a cage insertion tool is used to move each protrusion formed on the inclined surface of the first side body and the side of the body when the first side body is moved forward along each rail formed on the inclined surface of the second side body and the side of the body, thereby moving the second side body to the right and allowing the first side body to be located to the left side of the second side body. Therefore, without any need for complicated operation tools, minimally intrusive operation can be simply performed.

Description

Unidirectional expandable intervertebral body fusion cage device {UNIDIRECTIONAL EXPANDABLE INTERVERTEBRAL FUSION CAGE DEVICE}

The present invention relates to a unidirectional expandable intervertebral body fusion cage device, and more particularly, can stably support vertebrae by expanding the area occupied by the cage after being easily inserted between a vertebrae and neighboring vertebrae with minimal invasion during surgery. It relates to a unidirectional expandable intervertebral body fusion cage device that enables

In general, in the case of conventional open incision surgery for patient treatment, the incision site is large and the amount of blood loss during surgery is large, so the patient's recovery after surgery is slow, and large scars are left after surgery, which hinders the life of the patient.

In order to overcome the disadvantages of such open incision surgery, a new surgical technique called minimally invasive surgery (MIS) is being developed.

Minimally invasive surgery is a surgical technique in which a thin and long surgical tool specially designed to minimize the incision required for surgery is used to incise only a minimum area on the patient's body surface.

This minimally invasive surgery requires a small incision and significantly less blood loss during the procedure than open surgery, so it has the advantage of a fast recovery period for patients after surgery and a small externally visible scar, and the number of such procedures has increased significantly in recent years. It is increasing.

On the other hand, the disc existing between the vertebrae and bones functions as a joint, and plays a very important role in minimizing the impact applied to the spine by changing the position and shape of the nucleus pulposus accommodated inside the disc according to the movement of the spine.

Most of the nucleus pulposus is composed of water (water), but as the age increases, the water content gradually decreases, causing the disc to lose its buffering function.

As a result, when excessive pressure is applied to the fiber, back pain occurs, and when the fiber progresses further, the fiber is severely stretched or ruptured, pressing the nerve root located in the back, causing pain in the pelvis, legs, etc.

Since then, various side effects have occurred, such as the gradual narrowing of the space between the vertebrae and the deformity of the vertebrae as the vertebrae collapsed.

As one method of treating diseases caused by discs, there is a method of replacing a space between two adjacent vertebrae with a prosthetic material, a so-called cage, after removing the damaged intervertebral disc.

That is, the prosthetic material restores the original distance between two adjacent vertebral bodies, which is the original height of the intervertebral disc, to restore the spinal function.

As a surgical method of inserting such a prosthetic material between the vertebrae, ALIF (Anterior Lumbar Interbody Fusion), which opens the stomach and inserts the prosthetic material from the front of the spine, LLIF (Lateral Lumbar Interbody Fusion), which inserts the prosthetic material through the flank area, etc. There are things like TLIF (Transforaminal Lumbar Interbody Fusion), which inserts prosthetic materials in a diagonal direction at a point 30 to 40 mm from the center of the back, and PLIF (Posterior Lumbar Interbody Fusion), which inserts prosthetic materials from the back.

A prior art for inserting a prosthetic material between the vertebrae is Patent Registration No. 10-1674490 entitled 'Expandable Cage Device for Minimally Invasive Surgery'. Korean Patent Registration No. 10-1674490 discloses a main body inserted between a vertebra and an adjacent vertebra, and provided on both sides of the main body, and an area occupied by the main body inserted between the vertebra and the adjacent vertebra. and a variable unit for changing the main body, wherein the main body includes a first bone fusion space penetrating the front side of the main body and a first bone fusion space penetrating each side of the main body and communicating with the first bone fusion space part. A communication slot, a second fusion space passing through the main body and disposed on the rear side of the first fusion space, and passing through the main body and disposed between the first fusion space and the second fusion space a second communication slot that passes through both side surfaces of the main body and communicates with the operating space and the second osseointegration space, and to which the variable unit is coupled; and an insertion slot into which an insertion block, through which the variable unit protrudes from both sides of the main body and maintains an increased area, is inserted, and the first bone fusion space includes a piece of autologous bone or an artificial bone substitute. It is characterized by this filling.

Registered Patent No. 10-1674490 discloses that the variable unit is inserted into a vertebra and neighboring vertebrae while being housed in the main body, and then, when an insertion block is inserted, it is withdrawn from both sides of the main body and placed between the vertebrae and neighboring vertebrae. Although the support area is increased, the variable unit is an auxiliary means and is very different from the structure of the main body, so there is a problem with durability when used for a long time. There is a problem in which it is difficult to completely prevent the subsidence phenomenon.

Another prior art is Patent Registration No. 10-2097624 entitled 'Space Expansion Type Intervertebral Body Fusion Cage Device'. Regarding Patent No. 10-2097624, the variable unit is provided on both left and right sides of the main body, and when inserted between the first and second vertebrae, it is inserted in close contact with both left and right sides of the main body. do. After the variable unit is inserted between the first vertebra and the second vertebra, when the rear end is pushed, the joint part between the front end and the rear end is bent to the outside of the main body, and the part that is in close contact with the left and right sides of the main body distanced from

Regarding Patent Registration No. 10-2097624, as the joint part of the variable unit is bent to the outside of the main body, the parts that are in close contact with the left and right sides are separated from the main body, and a lot of space is created between the main body and the variable unit. Due to the space between the main body and the variable unit, there is a problem in that a stagnation phenomenon occurs between a vertebrae and a neighboring vertebrae when used for a long time.

Registered Patent No. 10-1674490 'Space expandable cage device for minimally invasive surgery' Registered Patent No. 10-2097624 'Space Expansion Type Intervertebral Body Fusion Cage Device'

The present invention was invented to improve the above problems, and after combining the first side body of the intervertebral body fusion cage device operated on the lumbar spine, cervical spine, vertebral body, etc. to the rear of the second side body, using a cage insertion tool to When the combined first side body is pushed forward, the first side body moves to the side of the second side body along the rail formed on the side of the front second side body, and the second side body located in the front moves to the right, and the first side body moves to the right. The body moves forward to provide a unidirectionally expandable intervertebral body fusion cage device in which a first side body and a second side body are positioned alongside each other to increase a support area between a vertebra and a neighboring vertebra.

In order to achieve the above object, the unidirectionally expandable intervertebral body fusion cage device according to the present invention forms a first inclined surface forwardly from the right side, and a first side body having protrusions formed on the first inclined surface and rearwardly from the left side. A second inclined surface is formed, and the second inclined surface includes a second side body on which a rail to which the protrusion is coupled is formed, and when the first side body is pushed in from behind, the first inclined surface is in contact with the second inclined surface and the protrusion is formed. While moving along the rail, the first side body moves forward, and the second side body is pushed to the right and moves.

The front portion of the first side body contacting the second inclined surface at the rear of the second side body has a front protrusion consisting of a protruding body and a protruding head larger than the diameter of the protruding body, and the second inclined surface at the rear of the second side body is formed at the front After the protrusion is inserted, a protrusion rail having a certain length is formed so that the protrusion head does not fall out while moving when the first side body is pushed in.

The front part of the first side body contacting the second inclined surface at the rear of the second side body has a front protrusion and a locking part, and the second inclined surface of the second side body has a through hole into which the locking part of the first side body is inserted. And, when the first side body is rotated after inserting the locking portion into the through hole, a semicircular rotation groove is formed on the second side body so that the front protrusion and the locking portion are rotatable, and after inserting the locking portion into the through hole When the first side body is rotated by the first angle, the first side body is fixed so as not to be separated from the rear of the second side body by the locking part, and after further rotating the first side body by the second angle, the first side body A front protrusion rail having a certain length is formed on the second inclined surface behind the second side body so that the protrusion head does not come off while the front protrusion moves when pushed in.

In addition, when the first side body is rotated after inserting the locking part into the through hole, the locking part moves along the semicircular rotation groove, and the front protrusion follows from the outside into the semicircular rotation groove.

In addition, a right side surface extending from the first inclined surface of the first side body is formed parallel to the longitudinal direction of the body, and a side projection portion composed of a protruding body and a protruding head larger than the diameter of the protruding body is formed, and is formed on the second inclined surface of the second side body. The following left surface is formed parallel to the longitudinal direction of the body, and a side protrusion rail having a certain length is formed so that the protrusion head does not come off while moving when the first side body is pushed in after the side protrusion is inserted.

Here, the end of the side protrusion rail is blocked so that the protrusion head of the side protrusion can no longer move forward.

According to the present invention having the configuration as described above, the following effects can be achieved.

When the first side body pushes and moves from the rear to the front and is positioned next to the second side body, the height of the first side body and the second side body are the same, and the two adjacent bodies (the first side body and the second side body) Since there is no empty space between the vertebrae, it is possible to completely prevent the stagnation phenomenon between vertebrae and neighboring vertebrae.

When the first side body is moved by pushing it forward using the cage insertion tool, it moves along the side rail of the second side body in front and the two side bodies are located side by side, so complicated treatment tools are needed. Minimally invasive surgery can be performed simply without

1 is a plan view and a partially enlarged view of a unidirectionally expandable intervertebral body fusion cage device of the present invention;
Figure 2 is a view (A) of the rear of the second side body and the front of the first side body when the unidirectional expandable intervertebral body fusion cage device is initially coupled, and rotated 45 degrees after fastening the first side body to the rear of the second side body The back of the second side body and the front view of the first side body in a state of being tightly coupled (B), the first side body is coupled to the second side body, and then rotated 90 degrees so that the projections of the first side body are attached to the second side body. Appearance when moving on the rail of the side body (C),
3 is a perspective view of a second side body;
Figure 4 is a view (A) when the first side body is coupled to the second side body to enter between the vertebrae, after the second side body is positioned between the vertebrae, the first side body is rotated 90 degrees to the first side The projection of the body moves forward along the rail of the second side body (B), and the projection of the first side body moves forward along the rail of the second side body to complete the procedure (C)

Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms.

In this specification, this embodiment is provided to complete the disclosure of the present invention, and to completely inform those skilled in the art of the scope of the invention to which the present invention belongs.

And the invention is only defined by the scope of the claims.

Thus, in some embodiments, well-known components, well-known operations and well-known techniques have not been described in detail in order to avoid obscuring the interpretation of the present invention.

In addition, like reference numerals designate like elements throughout the specification, and terms used (referred to) in this specification are for describing embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and components and operations referred to as 'comprising (or including)' do not exclude the presence or addition of one or more other components and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs.

In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The present invention will be described with reference to FIGS. 1 to 4 .

A unidirectionally expandable intervertebral body fusion cage device according to the present invention is composed of a first side body 100 and a second side body 200 . The first side body 100 and the second side body 200 are harmless to the human body and are made of titanium, titanium alloy, or polyether ether ketone (PEEK), depending on whether structural strength is prioritized or elasticity is prioritized. make up

During the procedure, the first side body 100 slides into the side of the second side body 200 along an inclined surface from the rear and is finally located next to the second side body 200 .

The second side body 200 moves by being pushed to the right while the first side body 100 pushes in from behind. In the drawings of the present invention, an example of moving by being pushed to the right is described, but it may be moved by being pushed to the left depending on the configuration. The first side body 100 and the second side body 200 are operated between vertebrae and neighboring vertebrae using the cage insertion tube 300, and through the cage insertion tube 300, the first side body ( 100) is operated using a separate treatment tool (not shown) that pushes the rear.

The first side body 100 forms a first inclined surface 150 from the right side to the front, and the protrusion 110 is formed on the first inclined surface 150.

The second side body 200 forms a second inclined surface 250 from the left side to the rear, and the rail 210 to which the protrusion 110 of the first side body 100 is coupled is formed on the second inclined surface 250. is formed

When the first side body 100 is pushed in from behind, the first side body 100 moves along the rail 210 while the protrusion 110 moves along the rail 210 in a state where the first inclined surface 150 is in contact with the second inclined surface 250. is moved forward, and the second side body 200 is pushed to the right to move.

The front part of the first side body 100 contacting the second inclined surface 250 at the rear of the second side body 200 has a protruding body 111 and a spherical protruding head 112 larger than the diameter of the protruding body 111. The formed front protrusion 110 is formed, and the second inclined surface 250 at the rear of the second side body 200 has a protrusion head 112 when the first side body 100 is pushed in after the front protrusion 110 is inserted. A protruding rail 210 of a certain length is formed so that it does not fall out while moving.

The front part of the first side body 100 in contact with the second inclined surface 250 at the rear of the second side body 200 has a front protrusion 110 and a locking part 120 formed, and the second side body 200 The second inclined surface 250 is formed with a through hole 220 into which the locking part 120 of the first side body 100 is inserted. The locking part 120 has a square column shape and is formed to a thickness that cannot be inserted into the protruding rail 210 .

When the first side body 100 is rotated to the right after inserting the locking portion 120 into the through hole 220, the second side body 200 allows the front protrusion 110 and the locking portion 120 to rotate. A semi-circular rotation groove 230 is formed therein. At the rear of the second side body 200, only one through hole 220 is formed to insert the locking part 120 of the first side body 100, and the front protrusion 110 of the first side body 100 It is not inserted into the through hole, and when the first side body 100 is rotated to the right, it comes along the inside of the semicircular rotation groove 230. Although the example of rotating the first side body 100 to the right has been described, when the positions of the first inclined surface 150 of the first side body 100 and the second inclined surface 250 of the second side body 200 are changed The first side body 100 is coupled by rotating it to the left.

After inserting the locking part 120 into the through hole 220, when the first side body 100 is rotated by a first angle, the first side body 100 is moved to the second side body 200 by the locking part 120. ) is fixed so as not to separate from the rear. Here, the first angle is preferably 45 degrees.

Referring to FIG. 2(A), the locking part 120 is inserted into the through hole 220.

Referring to FIG. 2 (B), then, when the first side body 100 is rotated 45 degrees to the right, the locking part 120 moves along the semicircular rotation groove 230 to move the first side body ( 100) is fixed so as not to be separated from the rear of the second side body 200. The locking part 120 first moves along the semi-circular rotation groove 230, and the front protrusion 110 follows it from the outside into the semi-circular rotation groove 230 and rotates along the rotation groove 230. do. Even if the first side body 100 is rotated 45 degrees to the right and the locking part 120 comes to a position facing the front protrusion rail 210, it does not go into the narrow front protrusion rail 210 due to the shape of the square pillar. and forward and backward movement within the semicircular rotational groove 230 is restricted.

Referring to FIG. 2(C), after the first side body 100 is further rotated by a second angle, when the first side body 100 is pushed in, the front protrusion 110 moves and the protrusion head 112 moves. A front protruding rail 210 of a certain length is formed on the second inclined surface 250 at the rear of the second side body 200 so as not to fall out. Here, the second angle is preferably 90 degrees. When rotated 90 degrees to the right from the state of FIG. 2 (B), the state of FIG. 2 (C) is obtained, and the front protrusion 110 faces the front protrusion rail 210 of the second side body 200. 2(C) shows a state in which the front protrusion 110 is ready to move along the front protrusion rail 210.

4(B) shows a state in which the front protrusion 110 of the first side body 100 moves forward along the front protrusion rail 210 of the second side body 200.

1 to 3, the right side extending from the first inclined surface 150 of the first side body 100 is formed parallel to the longitudinal direction of the body 100, and the protruding body 131 and the protruding body 131 A side protrusion 130 made of a protrusion head 132 larger than the diameter of is formed.

The left surface extending from the second inclined surface 250 of the second side body 200 is formed parallel to the longitudinal direction of the body 200, and when the first side body 100 is pushed in after the side protrusion 130 is inserted. A side protrusion rail 240 having a certain length is formed so that the protrusion head 132 does not come off while moving.

4(C) shows that the side protrusion 130 formed on the right side of the body of the first side body 100 is formed on the left side of the body of the second side body 200 as the first side body 100 is pushed further. It moves along the rail 240 and shows the first side body 100 and the second side body 200 positioned side by side.

The end of the side protrusion rail 240 is blocked to prevent the protrusion head 132 of the side protrusion 130 from moving forward any further.

Referring to FIG. 3, the end of the front protruding rail 210 of the second side body 200 is a front protruding rail with the end of the rail spread so that the protruding head 112 of the front protruding part 110 comes out of the rail. It forms the release surface 211. When the protrusion head 112 of the front protrusion 110 moves along the front protrusion rail 210 and the protrusion head 112 comes out of the front protrusion rail departure surface 211, the first side body 100 on the right side of the body The protrusion head 132 of the side protrusion 130 enters the side protrusion rail 240 through the side protrusion rail insertion surface 240, and the side protrusion 130 moves to the end along the side protrusion rail 240 to perform the procedure. will finish

Referring to FIG. 4, a procedure using the one-way expandable intervertebral intervertebral body fusion cage device of the present invention will be described.

First, as described in FIG. 2(A), the locking part 120 is inserted into the through hole 220 and then rotated 45 degrees to the right to fasten the first side body 100 to the rear of the second side body 200. do.

Referring to Figure 4 (A), in a state where the first side body 100 is fastened to the rear of the second side body 200, the cage insertion tube 300 is used to start insertion between the vertebrae and neighboring vertebrae. .

Referring to FIG. 4 (B), when the second side body 200 is positioned between the vertebrae, as described in FIG. 2 (C), the first side body 100 is rotated 90 degrees to the right and the first side body ( The front protrusion 110 of 100 moves along the front protrusion rail 210 of the second side body 200 .

Referring to FIG. 4(C), the first side body 100 is moved forward so that the front protrusion 110 of the first side body 100 is the front protrusion rail of the rear inclined surface 250 of the second side body 200. While moving on the 210, the side protrusion 130 on the right side of the body of the first side body 100 continues to move forward while riding the side protrusion rail 240 on the left side of the body of the second side body 200. When the first side body 100 moves to the blocked end of the side protrusion rail 240 and no longer moves forward, the procedure is completed.

When moving the first side body 100 forward, a separate cage insertion tool inserted into the cage insertion tube 300 is used.

As described above, the present invention combines the first side body constituting the intervertebral body fusion cage device operated on the lumbar spine, cervical spine, vertebral body, etc. to the rear of the second side body, and then connects the first side body to the rear using a cage insertion tool. When pushed forward, the first side body moves to the left side of the second side body along the rail formed on the left side of the front second side body, and the second side body moves to the right side to be supported between vertebrae and neighboring vertebrae. It is fundamental to provide a unidirectional expandable intervertebral body fusion cage device that increases the area and completely prevents stagnation between vertebrae and neighboring vertebrae without creating an empty space between the first side body and the second side body. It can be seen that it is done in a technical way.

And, of course, many other modifications and applications are possible to those skilled in the art within the scope of the basic technical idea of the present invention.

100 ... first side body
110 ... anterior projection
111, 131 ... projection body
112, 132... projection head
120 ... locking part
130 ... side projection
150 ... first slope
200 ... second side body
210 ... forward projection rail
211 ... forward projection rail departure surface
220 ... through hole
230 ... semicircular rotation groove
240...side projection rail
240... side projection rail insertion surface
250 ... 2nd slope
300 ... cage insertion tube

Claims (6)

A first side body that forms a first inclined surface from the right side forward and has a protrusion formed on the first inclined surface; and
A second side body that forms a second inclined surface from the left side to the rear, and a rail to which the protrusion is coupled is formed on the second inclined surface;
When the first side body is pushed in from the back, the first side body moves forward while the protrusion moves along the rail while the first inclined surface is in contact with the second inclined surface, and the second side body is pushed to the right and moves,
The front part of the first side body in contact with the second inclined surface at the rear of the second side body is formed with a front protrusion and a locking part,
The second inclined surface of the second side body is formed with a through hole into which the locking part of the first side body is inserted,
A semicircular rotation groove is formed on the second side body so that the front protrusion and the locking portion can rotate when the first side body is rotated after the locking portion is inserted into the through hole,
When the first side body is rotated by a first angle after the locking portion is inserted into the through hole, the first side body is fixed so as not to be separated from the rear of the second side body by the locking portion.
After the first side body is further rotated by a second angle, when the first side body is pushed in, a front protrusion rail of a certain length is formed on the second inclined surface behind the second side body so that the protrusion head does not fall out while the front protrusion moves. One-way expandable intervertebral body fusion cage device, characterized in that.
The method of claim 1,
The front portion of the first side body contacting the second inclined surface at the rear of the second side body has a front protrusion consisting of a protruding body and a protruding head larger than the diameter of the protruding body, and the second inclined surface at the rear of the second side body is formed at the front A one-way expandable intervertebral body fusion cage device, characterized in that a protrusion rail of a certain length is formed so that the protrusion head moves and does not fall out when the first side body is pushed in after the protrusion is inserted.
delete The method of claim 1,
When the first side body is rotated after inserting the locking part into the through hole, the locking part moves along the semicircular rotation groove, followed by the front projection coming into the semicircular rotation groove from the outside. Expandable intervertebral fusion cage device.
The method of claim 1,
A right side surface extending from the first inclined surface of the first side body is formed parallel to the longitudinal direction of the body, and a side projection portion composed of a protrusion body and a protrusion head larger than the diameter of the protrusion body is formed,
The left surface extending from the second inclined surface of the second side body is formed parallel to the longitudinal direction of the body, and when the first side body is pushed in after the side protrusion is inserted, a side protrusion rail having a certain length so that the protrusion head does not fall out while moving. One-way expandable intervertebral body fusion cage device, characterized in that formed.
The method of claim 5,
The end of the side protrusion rail is a one-way expandable intervertebral body fusion cage device, characterized in that the protrusion head of the side protrusion is blocked so that it no longer moves forward.

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