KR20230083524A - Cage for fusion of vertebrae - Google Patents

Abstract

The present invention relates to a cage for vertebral body fusion. The present invention is to enter between the vertebrae where the disc has been removed and maintain the spacing between the vertebrae. The present invention comprises: a rod connection part coupled to an end of a straight pushing rod; and a deflection extension of a certain width integrated with the rod connection, wherein the tip is provided with an entry guide slope inclined in the entry direction, and the deflection extension extends in a direction deflected with respect to the longitudinal direction of the pushing rod. In the cage for vertebral fusion of the present invention constructed as described above, the direction of the spikes is inclined with respect to the cage entry direction, so that the cage can be easily inserted by matching the entry direction of the cage to the direction of the spikes. In addition, the overall width is wide to support the vertebrae more stably, minimizing the stress on the pedicle screws and preventing breakage or loosening of the pedicle screws. In addition, since the direction of the spikes is located in the left and right directions of the vertebrae, there is no concern about posterior deviation due to movement of the upper body after surgery.

Description

Cage for fusion of vertebrae {Cage for fusion of vertebrae}

The present invention relates to a cage used for fusion of vertebrae, and more particularly, to a cage for fusion of vertebrae, having a structure that stably supports vertebrae and has no fear of posterior displacement after surgery.

Between the vertebrae that make up the human spine, intervertebral discs, usually called discs, are located. The intervertebral disc supports movement of the spine between upper and lower neighboring vertebrae, as well as absorbs and alleviates shock.

The intervertebral disc consists of the nucleus pulposus and the annulus fibrosus. The nucleus pulposus is a watery mucus that is soft and changes shape when pressed by an external force. For example, when the body is tilted to one side, the nucleus pulposus (in the annulus fibrosus) is driven to the side with less pressure, and when it is erected vertically, it gradually returns to its original position, the center.

In addition, the annulus fibrosus is a very tough and thick fiber, which wraps around the nucleus pulposus in a multi-layered state so that the nucleus pulposus does not leak out of the vertebrae. It is because the annulus fibrosus is firmly attached to the cartilaginous plate above and below the vertebrae that the disc is rigid and maintains adequate support.

However, when the annulus fibrosus is weakened or loses its elasticity and is torn, or a gap is created for other reasons, the degenerated nucleus pulposus inside the annulus fibrosus is expelled to the outside. This is called a herniated disc. Intervertebral disc herniation does not occur suddenly one day, but occurs when damage accumulates as more than the intervertebral disc can withstand, for example, as aging progresses, or due to causes such as excessive exercise or habitual bad posture.

There are various treatment methods for treating intervertebral disc herniation, and among them, spinal fusion is known as a surgical treatment method. Spinal fusion is a surgical method of implanting a prosthetic material for fusion, that is, a cage, between the upper and lower vertebrae after removing the damaged disc. It not only treats structural abnormalities such as the herniated intervertebral disc layer, And it is used for the purpose of fixing curvature, restoring anteriorly displaced vertebral body, and restoring the height of a fractured vertebral body.

There are various types of prosthetic materials for spinal fusion. Among them, Korean Patent Registration No. 10-1370424 (composite implant for spine) has a composite implant composed of a cage formed of resin material and a porous metal layer attached to the outer surface of the cage. is disclosed. However, since the disclosed composite implant is manufactured by thermally compressing a metal layer to a resin cage, the manufacturing process is cumbersome and, in particular, it is impossible to adjust the size. There was no For example, there is a risk of being easily dislodged while being inserted between the vertebrae.

The cage used for fusion of the vertebrae maintains the height of the vertebrae and has a shape that does not deviate from the vertebrae after surgery. In addition, the inside is hollow to accommodate the bone graft.

1 is a perspective view of a conventional vertebral bone fusion cage, and FIG. 2 is a view for explaining problems of the cage shown in FIG.

As shown, the cage 11 is a block-shaped member having a space 11a therein, and has a plurality of spikes 11b on the top and bottom surfaces. The spike 11b is driven into the surface of the opposing bone to keep the cage fixed. In addition, a female screw hole 11d is located at the rear of the cage 11 . As shown in FIG. 2, the female threaded hole 11d is a hole into which the pushing rod 13 engages. The pushing rod 13 is a rod-shaped tool used when inserting the cage 11 between the vertebrae.

However, in the conventional cage 11 described above, since the direction of the spike 11b is orthogonal to the longitudinal direction of the pushing rod 13, that is, the entry direction of the cage 11, the arrow between the vertebrae 100 It is not easy to enter direction a. This is because the spikes 11b are caught on the fine projections of the vertebrae on the opposite side.

In addition, even when a considerable amount of time has elapsed after the spinal fusion surgery, the cage 11 may be disengaged from the back of the vertebrae 100 by the movement of the upper body. For example, during movement, the cage 11 gradually falls backward due to the component force in the direction of arrow c generated when the cage 11 receives force in the direction of arrow b. If the cage falls backwards, it increases the chance of compressing or damaging a nerve. There is a demand for a cage with a stable structure that does not move the cage after surgery.

Domestic Patent No. 10-1370424 (Composite type implant for spine)

The present invention has been created to solve the above problems, and a cage for fusion of vertebrae can be easily inserted between the vertebrae, can support the vertebrae more stably, and there is no fear of separation after surgery. It is intended to provide

The cage for fusion of the vertebrae of the present invention as a means of solving the problems for achieving the above object is to enter between the vertebrae in a state in which the discs are removed, to maintain the distance between the vertebrae, and to be coupled to the end of the straight pushing rod a rod connection; It is integral with the rod connection part, and an entry guide slope inclined in the entry direction is provided at the front end, and includes a deflection extension of a certain width extending in a direction biased with respect to the longitudinal direction of the pushing rod.

In addition, the deflection angle of the deflection extension is characterized in that 10 to 20 degrees.

And, on the top and bottom surfaces of the cage facing the vertebrae, parallel serrated spikes having a constant pitch interval are formed, and the spikes have an angle of 40 to 50 degrees with respect to the extension direction of the deflection extension part. to be characterized

In addition, the maximum width between one end surface of the deflection extension portion in the width direction and the end edge portion of the rod connection portion in the width direction is larger than the width of the deflection extension portion.

And, in order to prevent damage to the nerve roots caused by the spikes, a spikeless portion without spikes is formed at the rear end of the cage.

In addition, a spare groove is further formed at the rear end of the cage to prevent damage to the nerve root caused by spikes.

In addition, the rod connection portion is formed with a female threaded hole screwed to the end of the pushing rod, and the free groove is symmetrical with the female threaded hole therebetween.

In addition, it is characterized in that the inside of the cage is formed with a space portion filled with bone grafts.

In addition, the cage is manufactured by a 3D printing method and is characterized in that it has a porous structure as a whole.

In addition, the cage is manufactured by a 3D printing method, and upper and lower surfaces in contact with the vertebrae are characterized in that they have a porous structure.

In the cage for fusion of vertebrae of the present invention as described above, since the direction of the spikes is inclined with respect to the direction of entry into the cage, the cage can be easily inserted by matching the direction of entry of the cage to the direction of the spikes.

In addition, the overall width is wide to more stably support the vertebrae, thereby minimizing the stress applied to the pedicle screws to prevent breakage or loosening of the pedicle screws.

In addition, since the direction of the spike is located in the left and right direction of the vertebrae, there is no concern about the backward deviation due to the movement of the upper body after surgery.

1 is a perspective view of a conventional vertebral bone fusion cage.
2 is a view for explaining problems of the cage shown in FIG. 1;
3 is a perspective view of a cage for fusion of vertebrae according to an embodiment of the present invention.
Figure 4 is a plan view of the cage for fusion of vertebrae shown in Figure 3;
5A to 5C are diagrams for explaining how the cage shown in FIG. 3 is used.
6 is a view showing a state in which the cage shown in FIG. 3 is inserted between vertebrae.
7 is a perspective view showing a modified example of a cage for fusion of vertebrae according to an embodiment of the present invention.
8 and 9 are diagrams showing another modified example of a cage for fusion of vertebrae according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

The cage for fusion of vertebrae according to the present invention supports vertebrae more stably and has a structure without fear of backward displacement after surgery, and includes a rod connection portion coupled to an end of a straight pushing rod; It is integral with the rod connection part, and an entry guide slope inclined in the entry direction is provided at the front end, and has a basic configuration of a deflection extension section of a certain width extending in a direction deflected with respect to the longitudinal direction of the pushing rod.

3 is a perspective view of a cage 20 for fusion of vertebrae according to an embodiment of the present invention, and FIG. 4 is a plan view of the cage for fusion of vertebrae shown in FIG. 3 .

As shown, the cage 20 for fusion of vertebrae according to the present embodiment includes a rod connection portion 20B and a bias extension portion 20A.

The cage 20 can be made of synthetic resin or metal. Polyetherether ketone (PEEK) can be used as the synthetic resin and titanium can be used as the metal. Like a general cage, the cage 20 enters between the vertebrae in a state in which the disc is removed, and maintains a distance between the vertebrae.

The rod connecting portion 20B has a female threaded hole 21d screwed to the end of the pushing rod 13. The central axis of the rod connecting portion 20B (Z1 in FIG. 5A) coincides with the central axis of the pushing rod 13. Also, the rod connecting portion 20B has a constant width W3.

The deflection extension part 20A is a part integral with the rod connection part 20B, and has an entry guide slope 21 at the front end. The entry guide slope 21 lowers the entry resistance when the cage 11 is entered between the vertebrae. The deflection extension portion 20A also has a constant width W1. The width of the deflection extension part and the width of the rod connection part are the same.

In particular, the central axis (Z2 in FIG. 5A) of the deflection extension portion 20A is deflected at a constant angle with respect to the longitudinal direction of the pushing rod 13. The above deflection angle θ1 is 10 degrees to 20 degrees, preferably 15 degrees.

As described above, since the rod connecting portion 20B and the deflection extension portion 20A are bent at an angle of 15 degrees, the maximum width between one end surface of the deflection extension portion in the width direction and the end edge of the rod connection portion in the width direction is greater than the width of the deflection extension portion.

That is, the width W2 between the one end surface 21e of the deflection extension part 20A in the width direction and the other corner part 21f in the width direction of the rod connecting part 20B is greater than the width W1 of the deflection extension part. . By bending the cage 11 and forming it, the maximum width W2 of the cage is formed larger than the width of the rod connection part or the deflection extension part itself.

By expanding the width of the cage 10 in this way, it is possible to more stably support the vertebrae. For example, it is much more difficult for the vertebrae supported by the cage 10 to tilt left and right around the cage, so that the fusion of the vertebrae can proceed more smoothly.

Reference numeral 21 denotes a space in which the bone graft is filled. When the cage 11 is inserted between the vertebrae, it is common to fill the bone graft inside the space 21a.

In addition, spikes 23 are formed on the upper and lower surfaces of the cage 20 that face the vertebrae. Each tooth of the spike 23 is parallel to each other and takes the shape of a tooth having a constant pitch. In particular, the spike 23 has a predetermined angle θ2 with respect to the extension direction of the deflection extension part 23 . The angle θ2 is between 40 degrees and 50 degrees, preferably 45 degrees.

As such, since the spikes 23 are inclined in an oblique direction, the spikes 23 of the cage 20 that have been inserted between the vertebrae 100 extend in the left and right directions of the vertebrae 100 . No matter how much the upper body is moved, there is no fear of leaving the cage 20 backward even if it can move left and right. For example, as shown in FIG. 6, even if the upper vertebra 100 moves in the direction of arrow m, the cage 20 does not fall backward.

Meanwhile, a spikeless part 25 is provided at the rear end of the cage 20 . The spikeless portion 25 is a curved portion that does not form a spike in order to prevent damage to the nerve root caused by the spike 23 . Since the spike 23 has a sharp shape, if there is no spikeless portion 25, when the nerve root is pinched between the vertebrae 100 and the cage 20 during surgery, the nerve cord will not be cut by the spike. can For this reason, the spikeless part 25 is applied to prevent damage to the nerve root. The spikeless portion 25 is symmetrical with respect to the female threaded hole 21d.

5A to 5C are diagrams schematically illustrating a mounting method of the cage 20, and FIG. 6 is a rear view illustrating a state in which a vertebra is viewed from behind after the cage 100 is mounted.

As shown in FIG. 5A, with the pushing rod 13 coupled to the cage 20, the cage 20 is moved in the direction of the arrow p to enter between the vertebrae 100. The back of the vertebrae 100 is blocked because the spinal cord or spinous process is located, so it is entered from the rear side as shown in FIG. 5a.

Figure 5b is a state in which the cage 20 is inserted, and Figure 5c is a state in which the cage 20 is completely inserted. As shown, the spike 23 pattern of the cage 20 extends in the left and right directions of the vertebrae 100, so the cage 20 cannot move back and forth.

7 is a perspective view showing a modified example of the cage 20 for fusion of vertebrae according to an embodiment of the present invention.

The same reference numerals as the above reference numerals indicate the same members with the same functions.

As shown, a clearance groove 26 is provided at the rear end of the cage 20. The spare groove 26 is a groove formed in the place of the spikeless part 25, and, like the spikeless part 25, is a groove for preventing damage to the nerve root caused by the spike.

The spare groove 26 is composed of a first groove 26a and a second groove 26b. The first groove 26a is a groove formed at the rear of the spike 23, and the second groove 26b is a groove located between the first groove 26a and the female screw hole 21d.

The clearance groove 26 has a depth sufficient to accommodate the nerve root, and can prevent compression or damage to the nerve root as well as cutting.

8 and 9 are views showing another modified example of the cage 20 for fusion of vertebrae according to an embodiment of the present invention.

As shown in FIGS. 8 and 9 , the cage 20 may be manufactured by 3D printing.

The cage 20 in FIG. 8 includes a body portion 31b and a porous portion 31a. The body portion 31b is a solid portion, and the porous portion 31a is a portion in which a plurality of pores are formed. The cage 20 shown in FIG. 9 is entirely formed of porous parts. Since the cage 20 manufactured by the 3D printing method can adjust the porosity, the fusion with the vertebrae can be more effective.

In the above, the present invention has been described in detail through specific embodiments, but the present invention is not limited to the above embodiments, and various modifications are possible by those skilled in the art within the scope of the technical idea of the present invention.

11: Cage 11a: Space 11b: Spike
11d: female screw hole 13: pushing rod 20: cage
20A: deflection extension part 20B: rod connection part 21: entry induction slope
21a: space part 21d: female screw hole 21e: one end
21f: corner part 23: spike 25: spikeless part
26: spare groove 26a: first groove 26b: second groove
31a: perforated part 31b: body part

Claims (10)

As it enters between the vertebrae with the disc removed and maintains the space between the vertebrae,
a rod connecting portion coupled to an end of the straight pushing rod;
A cage for fusion of vertebrae, characterized in that it is integral with the rod connection portion, has an entry guiding slope inclined in the entry direction at the front end, and includes a deflection extension portion of a certain width extending in a direction biased with respect to the longitudinal direction of the pushing rod. According to claim 1,
A cage for fusion of vertebrae, characterized in that the deflection angle of the deflection extension is 10 degrees to 20 degrees. According to claim 1 or 2,
Parallel serrated spikes having a predetermined pitch interval are formed on the upper and lower surfaces of the cage facing the vertebrae,
The spike is a cage for fusion of vertebrae, characterized in that it has an angle between 40 and 50 degrees with respect to the extension direction of the deflection extension. According to claim 2,
A cage for fusion of vertebrae, characterized in that a maximum width between one end surface in the width direction of the deflection extension part and a corner portion in the width direction of the rod connection part is greater than a width of the deflection extension part. According to claim 3,
At the rear end of the cage,
A cage for fusion of vertebrae, characterized in that a spikeless portion is formed in which spikes are not formed in order to prevent damage to nerve roots caused by spikes. According to claim 3,
At the rear end of the cage,
A cage for fusion of vertebrae, characterized in that a spare groove is further formed to prevent damage to the nerve root by spikes. According to claim 6,
In the rod connection portion, a female screw hole screwed with an end of the pushing rod is formed,
The free groove is a cage for fusion of vertebrae, characterized in that symmetrical with the female threaded hole therebetween. According to claim 1,
A cage for fusion of vertebrae, characterized in that a space portion filled with bone grafts is formed inside the cage. According to claim 1,
The cage is a cage for fusion of vertebrae, characterized in that it is manufactured by a 3D printing method and has a porous structure as a whole. According to claim 1,
The cage is manufactured by a 3D printing method, and the cage for fusion of vertebrae, characterized in that the upper and lower surfaces in contact with the vertebrae have a porous structure.

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