KR101272233B1 - An artificial disc for vertebra - Google Patents

Abstract

PURPOSE: A prosthetic disk for spine is provided to generate an effect of preventing side effects including bond erosion etc. by supporting a lower plate with a wing unit by arranging the wing unit which is formed on both sides of the lower plate in a frame unit which has a high density. CONSTITUTION: A prosthetic disk for spine comprises: a lower plate(110) equipped on a top central part of lower part spine; a connecting hole(120) fixed on the top of the lower plate, and formed with a first rotating surface which is shaped in a convex circular arc on the top thereof; and an upper plate(130) equipped in a bottom central part of the spine, and formed with a second rotating surface which is shaped in a concave circular arc on the bottom thereof. The upper plate is rotated according to the first rotating surface by contacting the first and second rotating surfaces. A wing unit(115) is equipped on both horizontal sides of the lower plate. The wing unit is protruded horizontally, and supports the lower plate by contacting the frame part of the lower part spine. The bottom of the wing unit is inclined more upward becoming closer to the outside of the lower plate. The wing unit is protruded 3mm outward from the lower plate, and inclined 20 degrees upward from the bottom.

Description

An artificial disc for vertebra

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spinal artificial disc, and more particularly to a spinal artificial disc that is implanted in place of a damaged disc between vertebrae to treat a disc related disease of the spine.

The artificial disc is inserted between the spine instead of the damaged disc when the spinal disc is in an unrecoverable state due to degenerative spinal stenosis or a traffic accident.

For example, degenerative spinal stenosis is as follows.

As the human body ages, degenerative changes occur in the spine and the gap between the vertebrae becomes closer, which causes spinal stenosis to compress the spinous process or the yellow ligaments that connect the spinal nerve or the spinal nerve. .

Treatment of spinal stenosis includes treatment with drugs, physical therapy, surgery.

Among these, surgical treatment is used when it is impossible to treat by other treatment methods, and it removes bones and tissues that compress the nerves and fixes the spine with screws in preparation for instability of the spine. Generally known.

However, the above surgical method requires removal of a wide range of bones and tissues, and requires general anesthesia, a long operation time and a long recovery period after surgery.

Therefore, elderly people who have weak energy are often unable to perform the operation, there is a problem that often occurs when complications and other reasons do not obtain a satisfactory effect, there was a problem that the operation costs too much.

One solution to this problem is to insert artificial discs in place of existing discs between the vertebrae.

Surgical treatment of inserting the artificial disk, there is a technique for fusion between the upper and lower vertebrae, and a technique for maintaining the mobility as before the disk is removed.

In the former case, the upper and lower vertebrae of which the disk is removed are integrated as they are integrated, thereby limiting mobility and flexibility as before the operation, which may cause inconvenience to the patient in daily life.

On the other hand, in the latter case, it is possible to maintain the same mobility and flexibility as before the operation, so that the spine can flow in response to the movement of the patient, there is an advantage that the patient does not feel a great inconvenience in maintaining daily life.

Figure 1 is a state diagram of the vertebrae showing the state in which the artificial disc used in the latter surgical method is inserted.

As shown in FIG. 1, a conventional artificial disc includes an upper plate 10 and a lower plate 20 fixed to the upper 60 and the lower 50 of the vertebra, in which the original disc is removed, and the upper plate 10. The intermediate plate 30 is inserted between the plate 10 and the lower plate 20, the upper plate 10, the lower plate 20 and the intermediate body 30 is formed in the upper surface or the lower surface is engaged with each other By the translational and rotational movement, the motility is imparted to the vertebrae.

However, the conventional spinal disc is seated in the center of the spine, the center of the spine is weak because there is a problem that the risk of bone invasion (bony invasion) to the vertebrae increases due to the continuous compression of the disc .

0001) Republic of Korea Patent No. 10-1087153. 0002) Republic of Korea Patent No. 10-0825357.

The present invention is to solve the above problems, the wing portion is formed on both sides of the lower plate to the spine during the implantation surgery to be in contact with the hard edge of the spine, not the center of the spine, it can prevent side effects such as bone erosion The purpose is to provide an artificial disc.

In order to achieve the above object, the artificial disk for spine of the present invention, the lower plate 110 is mounted to the upper central portion 51 of the lower vertebrae (50); A connector 120 fixed to an upper end of the lower plate 110 and formed with a convex arc-shaped first rotating surface 121 at an upper end thereof; An upper plate 130 mounted at a lower center of the upper vertebrae 60 and having a concave arc-shaped second rotating surface 132 formed at a lower end thereof; Including, but the upper plate 130 is rotated along the first rotating surface 121 in contact with the second rotating surface 132, the first rotating surface 121, on both sides in the horizontal direction of the lower plate 110, Protruding in the horizontal direction, the wing portion 115 is provided to support the lower plate 110 in contact with the upper edge portion 52 of the lower vertebrae (50).

The wing portion 115 is formed such that the bottom surface is inclined upward toward the outer direction of the lower plate (110).

The wing portion 115 is formed to protrude 3mm to the outside of the lower plate 110, it is formed to be inclined upward 20 degrees with respect to the bottom surface of the lower plate (110).

Long cylindrical hinge holes 113 are formed on both sides of the lower plate 110 in the longitudinal direction, and one end of the wing portion 115 in the lower plate 110 direction is inserted into the hinge hole 113. A hinge shaft 116 is formed to rotate the wing portion 115 in the up and down direction with respect to the lower plate 110.

The lower plate 110 and the upper plate 130 is made of an alloy material containing titanium or carbon, the connector 120 is made of a polyethylene material.

The artificial disk for spine of the present invention as described above has the following effects.

The wing portions 115 are formed on both sides of the lower plate 110 to be in contact with the dense and rigid rim 52 so that the wing portions 115 support the lower plate 110 to damage the vertebrae. It causes the effect of preventing side effects such as bone erosion.

As the lower end surface of the wing portion 115 is inclined upwardly, the contact area between the wing portion 115 and the edge portion 52 is maximized to improve the supporting force, thereby lowering the support plate 110. By further reducing the impact and load applied, the risk of side effects such as bone erosion is reduced.

The wing portion 115 is mounted to both sides of the lower plate 110 to be rotated in the vertical direction, thereby freely adjusting the up and down angle of the wing portion 115 according to the size of the spine of the patient, so that the wing portion 115 is It is to be precisely disposed on the rim 52 of the vertebrae, and generates the effect of allowing the lower plate 110 to be stably supported.

The upper plate 130 is mounted to be rotated at a predetermined angle in all directions along the first rotation surface 121, so that the upper vertebrae 60 can move at a predetermined angle with respect to the lower vertebrae 50 so that the patient after surgery It produces the effect of enabling spine movement.

1 is a structural diagram showing a state of the vertebrae implanted with a spinal artificial disc according to the prior art,
2 is a perspective view of an artificial disk for spine according to an embodiment of the present invention,
3 is an exploded perspective view of an artificial disc for a spine according to an embodiment of the present invention;
Figure 4 is a cross-sectional view of the artificial disk for the spine according to the embodiment of the present invention,
Figure 5 is a plan view showing a position where the artificial disk for spinal implants in accordance with an embodiment of the present invention,
6 is a partially exploded perspective view of an artificial disc for a spine according to another embodiment of the present invention;
Figure 7 is a cross-sectional view of the artificial disk for the spine in accordance with another embodiment of the present invention.

2 is a perspective view of an artificial disk for a spine according to an embodiment of the present invention, FIG. 3 is an exploded perspective view of an artificial disk for a spine according to an embodiment of the present invention, and FIG. 4 is a view of an artificial disk for a spine according to an embodiment of the present invention. 5 is a plan view showing a position where the artificial disk for spine is implanted according to an embodiment of the present invention, Figure 6 is a partially exploded perspective view of the artificial disk for spine according to another embodiment of the present invention, Figure 7 is a view of the present invention A cross-sectional view of an artificial disc for a spine according to another embodiment.

As shown in FIGS. 2 to 5, the artificial disc for the spine according to the embodiment of the present invention includes a lower plate 110, a connector 120, and an upper plate 130.

In general, between all the vertebrae, including the lumbar spine, thoracic and cervical vertebrae, there is a disc, in other words cartilage, called the intervertebral disc, which functions to flexibly connect the vertebrae to absorb shocks and enable movement.

When the disc of the cervical spine is damaged, it is removed and the artificial disc of the present invention manufactured artificially is implanted between the vertebrae.

Specifically, the lower plate 110 is mounted on the upper end of the lower vertebrae 50 disposed below the space from which the disk is removed, and is formed in a substantially rectangular plate shape.

A plurality of pins 111 protrude from the lower plate 110, and the pins 111 are fixed to the upper end of the lower vertebrae 50.

Here, the lower plate 110 is disposed in the central portion 51 of the lower vertebrae 50.

That is, as shown in FIG. 5, the lower vertebrae 50 are located at the center 51 when viewed in a plane.

In addition, a circular mounting groove 112 is formed at the upper end of the lower plate 110.

The connector 120, which will be described later, is inserted into and fixed to the mounting groove 112, and is fixed by bonding with an adhesive or the like, and may be manufactured in a fixed state by insert injection.

The lower plate 110 is made of a titanium or carbon alloy of a metal material.

The lower plate 110 is implanted inside the body, and since the impact and load on the spine must be buttered for a long time, high strength and harmless to the human body, such as titanium or carbon metal is suitable.

In addition, as shown in FIG. 3, wings 115 are formed on both sides of the lower plate 110 in the horizontal direction.

The wings 115 are formed in a rectangular shape and protrude in the horizontal direction, respectively, and are disposed to contact the edge portion 52 of the lower vertebra 50.

Here, the central portion 51 of the lower vertebrae 50 has a weaker bone density than the edge portion 52.

For this reason, conventionally, when a long time passes after the artificial disc is implanted in the central portion 51, the artificial disk damages the central portion of the vertebrae 51, thereby increasing the risk of resting.

However, the artificial disk for the spine according to the present invention, the bone portion is damaged because the bone 115 is placed in contact with the dense and rigid edge portion 52 to additionally support the lower plate 110. It produces the effect of preventing erosion.

In addition, the wing portion 115 is formed to be inclined upward gradually toward the outer side of the lower plate 110 in the lower direction.

That is, the wing portion 115 is formed in a shape bent obliquely upward.

Here, the rim 52 of the vertebrae protrudes higher than the central portion 51 to generate a height difference. The bottom surface of the wing portion 115 is formed to be inclined upwardly, whereby the bottom surface of the lower plate 110 is formed. In the state mounted on the central portion 51, the wing portion 115 is widely contacted along the surface of the edge portion 52 to maximize the contact area and the supporting force.

As such, the bottom surface of the wing portion 115 is formed to be inclined upwardly, thereby increasing the contact area between the wing portion 115 and the edge portion 52 as much as possible, thereby improving the bearing force, and thereby the lower plate ( 110) to reduce the impact and load to reduce the risk of side effects such as bone erosion.

In addition, as shown in Figure 4, the width (a) of the transverse direction of the wing 115 is 3mm, the angle (b) between the bottom surface of the lower plate 110 and the bottom surface of the wing 115 ) Is 20 degrees.

These dimensions are standard values calculated for the average vertebral size of an adult and are widely available.

In addition, the wing 115 is made of the same material as the lower plate 110, it is formed integrally.

Of course, in some cases, the wing unit 115 may be formed as a separate object from the lower plate 110, it may be configured to be assembled together.

6 and 7, the wing 115 is formed separately from the lower plate 110 and may be rotatably mounted on both sides of the lower plate 110 in the horizontal direction.

In this case, a long cylindrical hinge hole 113 is formed in both sides of the lower plate 110 in the horizontal direction.

In addition, a hinge shaft 116 inserted into the hinge hole 113 is formed at one end of the wing portion 115 in the lower plate 110.

The hinge shaft 116 is formed in a long cylindrical shape in the longitudinal direction, is inserted into the hinge hole 113 is rotated by a predetermined angle in the vertical direction.

As such, the wing portion 115 is mounted to both sides of the lower plate 110 to be rotated in the vertical direction, thereby freely adjusting the angle of the wing portion 115 according to the size of the spine of the patient so that the wing portion 115. ) Is precisely disposed on the rim 52 of the vertebrae, and generates an effect of stably supporting the lower plate 110.

On the other hand, the connector 120 is formed in a hemispherical shape, and is fixed to the mounting groove 112 formed on the upper end of the lower plate (110).

In addition, the upper end of the connector 120 is formed with a convex arc-shaped first rotating surface 121.

The first rotation surface 121 is in contact with the upper plate 130 to be described later to support the upper plate 130 to be rotated.

The connector 120 is made of a polyethylene material unlike the lower plate 110, it is preferably formed to be flexible to have a slight elastic force.

The upper plate 130 is mounted at the lower center of the upper vertebrae 60 disposed on the upper vertebrae 50.

The upper plate 130 is formed in the shape of a square plate like the lower plate 110, a plurality of pins 131 protrudes on the upper end, the pins 131 are embedded in the lower end of the upper vertebrae 60 It is fixed.

In addition, the lower end of the upper plate 130 is formed with a circular arc-shaped second rotating surface 132 in the upward direction.

The second rotating surface 132 is in contact with the first rotating surface 121 so that the upper plate 130 is rotated at an angle in four directions, such as horizontal and vertical along the surface of the first rotating surface 121.

That is, the upper plate 130 is inclined to rotate at a predetermined angle while the second rotating surface 132 moves along the curved surface of the first rotating surface 121.

Here, it is preferable to make the circular arc diameter of the said 2nd rotating surface 132 and the circular arc diameter of the said 1st rotating surface 121 the same.

As such, the upper plate 130 is mounted to be freely rotated along the first rotation surface 121, so that the upper vertebra 60 can move at a predetermined angle with respect to the lower vertebra 50. It produces the effect of enabling spine movement.

As described above, the artificial disc for the spine according to the embodiment of the present invention, while the upper plate 130 is freely rotated along the first rotation surface 121 of the connector 120, while freeing the spine movement of the patient, the wing portion ( 115 is disposed on the rim 52 of the vertebrae to support the lower plate 110, thereby reducing the load on the central portion 51 of the vertebrae, thereby risking side effects such as bone erosion that damages the vertebrae. To reduce the effect.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims something to do.

50: lower vertebra, 60: upper vertebra,
110: bottom plate, 112: mounting groove,
113: hinge ball, 115: wing,
116: hinge axis, 120: connector,
121: first rotating surface, 130: top plate,
132: second rotating surface,

Claims (5)

A lower plate 110 mounted at the upper center portion 51 of the lower vertebrae 50;
A connector 120 fixed to an upper end of the lower plate 110 and formed with a convex arc-shaped first rotating surface 121 at an upper end thereof;
An upper plate 130 mounted on a lower center portion 51 of the upper vertebrae 60 and having a concave arc-shaped second rotating surface 132 formed at a lower end thereof; Including,
The top plate 130 is rotated along the first rotating surface 121 in contact with the second rotating surface 132, the first rotating surface 121,
On both sides of the lower plate 110 in the horizontal direction, protruding in the horizontal direction, in contact with the upper edge portion 52 of the lower vertebrae 50 is characterized in that the wing portion 115 for supporting the lower plate 110 is provided. Artificial disk for spine.
The method of claim 1,
The wing portion 115 is an artificial disk for the spine, characterized in that the lower surface is inclined upward toward the outer direction of the lower plate (110).
3. The method of claim 2,
The wing portion 115 is formed to protrude 3mm to the outside of the lower plate 110, the artificial disk for the spine, characterized in that formed to be inclined upward 20 degrees with respect to the bottom surface of the lower plate (110).
The method according to any one of claims 1 to 3,
On both sides of the lower plate 110, long cylindrical hinge holes 113 open in the longitudinal direction are formed, respectively.
The hinge shaft 116 is inserted into the hinge hole 113 at one end of the wing portion 115 in the direction of the lower plate 110 to rotate the wing portion 115 in the vertical direction with respect to the lower plate 110. An artificial disc for spine, characterized in that formed.
The method according to any one of claims 1 to 3,
The lower plate 110 and the upper plate 130 is made of an alloy material containing titanium or carbon, the connector 120 is a spinal artificial disk, characterized in that made of polyethylene material.

Images