KR102028427B1 - Intervertebral Fusion Cage With Improved Fixation - Google Patents

Abstract

The present invention relates to an intervertebral fusion cage with improved fixation force, and more particularly, a body portion inserted into a space between neighboring vertebral bones, and a portion of the body when coupled to the body portion and the body portion is positioned. It consists of a fixing part that protrudes outwardly and is inserted into the vertebral bone, and the cage used for spinal fixation is positioned in a preplanned position, and then the cage is fixed by various causes before the union of the vertebral bone occurs. The intervertebral fusion cage, which solves the problem of deviating from the position by increasing the fixing force of the cage through the fixing portion.

Description

Intervertebral Fusion Cage With Improved Fixation

The present invention relates to an intervertebral fusion cage with improved fixation force, and more particularly, a body portion inserted into a space between neighboring vertebral bones, and a portion of the body when coupled to the body portion and the body portion is positioned. It consists of a fixing part that protrudes outwardly and is inserted into the vertebral bone, and the cage used for spinal fixation is positioned in a preplanned position, and then the cage is fixed by various causes before the union of the vertebral bone occurs. The intervertebral fusion cage, which solves the problem of deviating from the position by increasing the fixing force of the cage through the fixing portion.

The spine forms the longitudinal axis of the body, with seven cervical vertebras, twelve thoracic vertebras, five lumbar vertebras, five sacrums, and four tailbones (coccyx). Spinal bones composed; Spinal disc, also called the intervertebral disc, which is a discoid cartilage structure connecting the vertebral bone with the vertebral bone; Is done.

In general, the vertebral disc absorbs the load and impact of the body between the vertebral bones, acts as a shock absorber to disperse the impact like a spring, holds the vertebral bones away, and separates the vertebral nerves from compression. It makes the range of vertebral joints smooth, and plays a role of smoothing the movement of each vertebral bone.

The spinal disc of such a person usually consists of a fibrous ring and a nucleus pulposus. If the water in the water balloon is the nucleus pulposus, the fibrous ring corresponds to a rubber balloon containing water.

If you develop a degenerative disc disease, the movement of the annulus or the nucleus of the nucleus will be weakened, leading to a decrease in the water content of the spinal disc, resulting in spinal stenosis, osteophyte formation, and disc prolapse. Diseases such as Lumbar Herniated Intervertebral Disc) and nerve root compression may occur.

As a method for treating a disease related to the vertebral disc, a method is used in which a space between two adjacent vertebral bodies is replaced by a cage after the intervertebral disc of the damaged human body is removed. This combines two adjacent vertebral bodies to limit the movement of the vertebrae, thereby repairing the pain causing vertebrae by restoring the original distance between two adjacent vertebral bodies, the original height of the intervertebral disc.

The cage has an appropriate thickness and anatomical type to restore the original height of the intervertebral disc, and holes are formed in the inner side to facilitate bone growth by inserting a bone graft. And it has a form having a mounting hole for mounting on the insertion tool.

In the case of lumbar spine, Posterior Lumbar Interbody Fusion (PLIF), Transforaminal Lumbar Interbody Fusion (TLIF), and Lumbar Interbody Fusion (ALIF) ), And direct lateral interbody fusion (DLIF). In the case of the cervical spine, the cage is used as an anterior cervical interbody fusion (ACIF) or anterior cervical discectomy and fusion (ACDF).

1 is a view of a cage assembly for intervertebral fusion surgery in the prior art, which is disclosed in Republic of Korea Patent Publication No. 10-1632908 (June 17, 2016). Referring to Figure 1, the conventional cage 90 is the first insertion portion 91 is formed to be inclined to facilitate the insertion, the thread 93 is formed on the upper and lower surfaces of the cage in contact with the vertebrae. The inside of the cage is provided with a space 95 into which a bone graft is inserted, and a slot 97 communicating with the space 95 is configured to check bone growth.

However, in the case of the conventional cage 90, before the complete union between neighboring vertebrae occurs, the cage 90, which was positioned in the correct position during the surgery, may be displaced due to various causes. Problems may arise. When the cage 90 is out of its original position, problems such as a decrease in union rate, nonunion, subsidence, and dislocation due to initial fixation failure may occur, which may require reoperation due to side effects. Not only does this cause a lot of pain, but it also incurs a waste of money and time for additional surgery.

Therefore, the relevant industry has developed a cage 90 of a new method that can secure the cage 90 firmly between the vertebral bones simply by simple positioning after the cage 90 is correctly positioned in a pre-planned position to prevent the positional deviation. The situation is demanding.

The present invention has been made to solve the above problems,

An object of the present invention, the body is coupled to the body portion when the body portion is positioned to constitute a part that protrudes in the outward direction of the body portion and inserted into the vertebral bone, the cage used for spinal fixation surgery Intervertebral body, which solves the problem of the cage being displaced by various causes before the union of the vertebral bone after positioning on the preplanned position by increasing the fixing force of the cage through the fixing part. To provide a fusion cage.

Another object of the present invention is to form a fixed portion including a peg portion coupled to the body portion to enable the lifting and lowering, and the propulsion unit for raising and lowering the peg portion, the pushing portion of the peg portion just by pulling or pulling It is to provide an intervertebral fusion cage, which allows induction of the lowering.

Still another object of the present invention includes a head portion contacting orthogonal to the propulsion shaft of the propulsion portion, one end coupled to the head portion, and a shaft portion extended vertically, and a spike portion coupled to the other end of the shaft portion to form an inclined surface. By constructing a peg part, the intervertebral fusion cage is inserted between the vertebral bones of the patient and positioned, and then the head part is pushed by the pushing part so that the shaft part moves outward of the body part. By making it easy to get into the vertebral bone, it is to provide an intervertebral fusion cage with a high fixing force on the vertebral bone so that the cage does not leave in place before the fusion of the vertebral bone occurs.

Another object of the present invention is configured on the upper side and the lower side, respectively, based on the center horizontal plane of the body portion by configuring the upper and lower pegs in synchronizing up and down, so as to simply push the pushing portion between the upper and lower pegs It is to provide an intervertebral fusion cage, which allows both upper and lower peg portions to simultaneously move outward of the body portion and be inserted into the vertebral bone.

Still another object of the present invention is configured on the left and right sides based on the center vertical surface of the body portion, respectively, and the left and right peg portions are configured to move up and down, so that both the peg portions on the left and right sides at the same time just by pushing the pressing portion of the pushing portion An intervertebral fusion cage is provided, which can be moved outwardly and inserted into the vertebral bone.

Still another object of the present invention is to provide an intervertebral fusion cage in which the head portion has a hemispherical shape having a curved surface, so that the pressing portion having the inclined surface can easily push the head portion.

Still another object of the present invention is to enter between the head portion of the upper and lower peg portion for synchronization of the upper and lower peg portion, pushing the head portion to the outside of the body portion, and connecting the pressing portion formed on each of the left and right sides for synchronization of the left and right peg portion And a coupling portion coupled to the center of the coupling portion and receiving a driving force from the outside, even though a plurality of pegs are formed on the body portion, the coupling portion is moved through the coupling portion, and a plurality of pressing portions coupled to the coupling portion are simultaneously connected to the peg portion. By pressurizing, it is to provide an interbody vertebral cage, in which a plurality of pegs are synchronized with each other.

Still another object of the present invention is to construct a pressing portion including a pair of inclined surfaces inclined at different angles with respect to the central horizontal plane of the end portion, such that the hemispherical head portion is vertically pushed along the inclined surface of the pressing portion. It is to provide an intervertebral fusion cage, which allows the peg portion of the upper, lower, left and right sides to move simultaneously to the outside of the body portion and to be inserted into the vertebral bone by simply pushing the pressing portion.

Still another object of the present invention is to form a locking portion protruding forward from the center of the connecting portion, by rotating the coupling portion in one direction with a surgical instrument to move the connecting portion in contact with the coupling portion to the rear side, and then the surgical instrument In the case of moving the coupling part in the other direction and moving the front side, the connecting part is not moved forward. The intervertebral fusion cage, which moves the connecting part anteriorly by allowing the surgical tool to be fastened to the locking part when the surgical tool is rotated in the other direction, To provide.

Still another object of the present invention is to provide a intervertebral fusion cage, which constitutes a thread protruding along the outer circumferential surface of the coupling portion, so that the coupling portion can move in a horizontal linear motion by rotation.

Still another object of the present invention is to configure a coupling portion that is coupled with the connection portion such that the rotational force of the coupling portion is not transmitted to the connection portion, and only the driving force of the coupling portion among the rotational force and propulsion force of the coupling portion horizontally moving by rotation. It is to provide an intervertebral fusion cage, which allows delivery, so that the connection can only be horizontal in movement without rotation.

Still another object of the present invention is a peg part accommodating hole having a shape for accommodating the peg part, a press part accommodating hole having a shape in communication with the peg part accommodating hole and accommodating the press part, The body part includes a connection part accommodating hole communicating with the connecting part accommodating hole and having a shape accommodating the accommodating part accommodating the accommodating part accommodating hole, the peg part being separated from the peg accommodating hole. It is to provide an intervertebral fusion cage, so that the pressing portion and the connecting portion is movably seated and protected inside the body portion, and guides the rotational movement of the coupling portion.

Still another object of the present invention is to configure a peg part accommodating hole for accommodating the shaft part of the peg part, so that the head part and the spike part of the peg part are not accommodated in the peg part accommodating hole so that the head part determines the outer projection limit of the peg part, It is to provide an interbody fusion cage, the spike portion to determine the inner acceptance limit of the peg portion.

Still another object of the present invention is to construct a protrusion formed on the upper and lower surfaces of the body portion, so that the fixing force by the frictional force on the upper and lower surfaces of the body portion in contact with the vertebral bone after positioning the intervertebral union cage in place. To provide a hepatic fusion cage.

Another object of the present invention, by forming the projections to the height of the spike portion, to prevent the problem that the spikes caught on the vertebral bones in the process of pushing the intervertebral fusion cage into the space between the vertebral bone of the patient to prevent the cage propulsion To provide interbody fusion cages.

The present invention is implemented by the embodiment having the following configuration to achieve the above object.

According to an embodiment of the present invention, the present invention includes a body portion and a part coupled to the body portion when the body portion is positioned, the portion protruding outwardly of the body portion and inserted into the vertebral bones. It features.

According to another embodiment of the present invention, the fixing part, characterized in that it comprises a peg portion coupled to the body portion to enable the lifting and lowering, and a propulsion unit for lifting up and down the peg part.

According to another embodiment of the present invention, the peg portion is characterized in that it comprises a head portion in contact with the propulsion shaft orthogonal to the propulsion portion.

According to another embodiment of the present invention, the peg portion is characterized in that it comprises a shaft portion extending vertically while being coupled to form a step with the head portion.

According to another embodiment of the present invention, the peg portion is characterized in that it comprises a spike portion to form an inclined surface coupled to form a step with the shaft portion.

According to a further embodiment of the present invention, the peg part is configured on the upper side and the lower side with respect to the center horizontal plane of the body portion, it characterized in that the upper and lower peg portion is moved up and down in synchronization.

According to another embodiment of the present invention, the peg part is configured on the left and the right side with respect to the center vertical surface of the body part, characterized in that the left and right peg parts are moved up and down in synchronization.

According to still another embodiment of the present invention, the head portion has a hemispherical shape with a curved surface.

According to a further embodiment of the present invention, the propulsion unit, between the upper and lower peg part head portion for the synchronization of the upper and lower peg part to push the head portion to the outside of the body portion, and the left and right peg part synchronization It characterized in that it comprises a connecting portion for connecting the pressing portion formed on each of the left and right, coupled to the connecting portion to receive a driving force from the outside.

According to another embodiment of the present invention, the present invention is characterized in that the pressing portion includes a pair of inclined surfaces inclined in different directions at the same angle with respect to the center horizontal plane of the end.

According to another embodiment of the present invention, the present invention is characterized in that the connection portion further comprises a locking portion protruding forward.

According to still another embodiment of the present invention, the present invention is characterized in that the coupling part includes a screw thread protruding along the outer circumferential surface.

According to another embodiment of the present invention, the coupling portion, characterized in that coupled to the connecting portion, so that the rotational force of the coupling portion is not transmitted to the connecting portion.

According to another embodiment of the invention, the present invention, the body portion, a peg part receiving hole having a shape for accommodating a peg part, a pressure part accommodating hole having a shape in communication with the peg part accommodating hole and receiving a pressing part And a connecting part accommodating hole communicating with the pressing part accommodating hole and having a shape accommodating the connecting part, and a connecting part accommodating hole having a shape communicating with the connecting part accommodating hole and accommodating the coupling part.

According to another embodiment of the present invention, the peg part receiving hole is characterized in that for receiving the shaft portion of the peg part.

According to another embodiment of the present invention, the present invention is characterized in that the body portion further comprises a protrusion formed on the upper and lower surfaces.

According to still another embodiment of the present invention, the present invention is characterized in that the protrusion is formed above the height of the spike portion.

The present invention can obtain the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention comprises a body portion and a fixing portion which is coupled to the body portion and the portion is protruded outwardly of the body portion and inserted into the vertebral bone when the body portion is positioned, so that the cage used for the spinal fixation is beforehand. An intervertebral fusion cage, which solves the problem of the cage being displaced in place by various causes after positioning on the planned position, before fusion of the vertebral bone occurs. Has the effect of providing.

The present invention constitutes a fixing part including a peg part coupled to the body part and a propelling part for elevating the peg part to enable the elevating, and thus inducing the peg part to move up and down by simply pushing or pulling the pushing part. The effect of providing intervertebral fusion cages is obtained.

The present invention comprises a peg portion including a head portion contacting orthogonal to the propulsion shaft of the propulsion portion, one end coupled to the head portion, and a shaft portion extended vertically, and a spike portion coupled to the other end of the shaft portion to form an inclined surface. By inserting and positioning the intervertebral fusion cage between the vertebral bones of the patient, the head portion is pushed by the pushing portion so that the shaft portion moves outward, and the spike portion coupled with the shaft portion is easy to the vertebral bone. In this way, it is effective to provide an intervertebral fusion cage, which has a high fixing force on the vertebral bones so that the cage does not leave in place before fusion of the vertebral bones occurs.

According to the present invention, the upper and lower pegs are respectively configured on the upper and lower sides with respect to the center horizontal plane of the body, so that the upper and lower pegs are synchronized to move up and down, so that the upper and lower pegs are pushed between the upper and lower pegs. It has the effect of providing an intervertebral fusion cage, which allows the peg portion to simultaneously move outward of the body portion and be inserted into the vertebral bone.

According to the present invention, the left and right pegs are configured on the left and right sides with respect to the center vertical surface of the body, respectively, so that the left and right pegs are synchronized to move up and down. The effect is to provide an intervertebral fusion cage that can be inserted into the vertebral bone.

The present invention has the effect of providing an intervertebral fusion cage in which the head portion has a hemispherical shape having a curved surface, so that the pressing portion having the inclined surface can easily push the head portion.

The present invention, the pressing portion which enters between the upper and lower peg portion head portion for the synchronization of the upper and lower pegs, and pushes the head portion to the outside of the body portion, and the connecting portion connecting the pressing portion formed on each of the left and right sides for synchronization of the left and right pegs; By coupling to the center of the connection portion to configure the coupling portion to receive a propulsion force from the outside, even if a plurality of peg portion on the body portion by moving the connection portion through the coupling portion and by pressing a plurality of pressing portions coupled to the connection portion at the same time, It has the effect of providing an intervertebral fusion cage, in which a plurality of peg portions are synchronized to move up and down.

The present invention constitutes a pressing portion including a pair of inclined surfaces inclined at different angles at the same angle with respect to the central horizontal plane of the end portion, and pushes the pressing portion by pushing the hemispherical head portion vertically along the inclined surface of the pressing portion. Just by inserting, the upper, lower, left and right pegs simultaneously move to the outside of the body portion to derive the effect of providing an intervertebral fusion cage, which can be inserted into the vertebral bone.

The present invention comprises a locking portion protruding to the front side in the center of the connecting portion, by rotating the coupling portion in one direction with the surgical instrument to move the connecting portion in contact with the coupling portion to the rear side, and then hit the coupling portion with the surgical instrument In the case of forward movement by rotating in the direction, the connection portion does not move forward, the effect of providing a fusion between the intervertebral fusion cage, by moving the connecting portion to the front, so that the surgical instrument is fastened to the engaging portion when the other direction rotation of the surgical instrument There is.

The present invention has the effect of providing an intervertebral fusion cage, which constitutes a thread formed protruding along the outer circumferential surface of the coupling portion, so that the coupling portion can move in a horizontal linear motion by rotation.

The present invention constitutes a coupling portion coupled with the connection portion such that the rotational force of the coupling portion is not transmitted to the connection portion, so that only the driving force of the coupling portion is transmitted to the connection portion among the rotational force and the driving force of the coupling portion horizontally moving by rotation. The effect of providing an intervertebral fusion cage is obtained, which allows the connection to be horizontal only without rotation.

The present invention includes a peg part accommodating hole having a shape for accommodating the peg part, a press part accommodating hole communicating with the peg part accommodating hole and having a shape accommodating the press part, and communicating with the press part accommodating hole and the connection part. A body part including a connection part accommodating hole having a shape accommodating and a connection part accommodating hole communicating with the connection part accommodating hole and having the shape accommodating the accommodating part, so that the peg part is not separated from the peg part accommodating hole, The pressurizing portion and the connecting portion are movably seated and protected inside the body portion, and there is an effect of providing an intervertebral fusion cage, which guides rotational movement of the coupling portion.

The present invention constitutes a peg part accommodating hole for accommodating a shaft part of a peg part, so that the head part and the spike part of the peg part are not accommodated in the peg part accommodating hole, so that the head part determines the outer projection limit of the peg part, and the spike part is the peg part. It has the effect of providing an intervertebral fusion cage, which allows the negative medial acceptance limit to be determined.

The present invention, by forming a protrusion formed on the upper and lower body parts of the body portion, the intervertebral fusion cage to increase the fixing force by the friction force on the upper and lower surfaces of the body portion in contact with the vertebral bone after positioning the intervertebral fusion cage in position. Derive the effect it provides.

The present invention provides a vertebral fusion, in which a protrusion is formed above the height of the spike portion, thereby preventing the spike portion from being caught by the vertebral bone and preventing the cage from being propelled in the process of pushing the intervertebral fusion cage into the space between the vertebral bones of the patient. It has the effect of providing a cage.

1 is a view of the cage assembly for intervertebral fusion fusion in the prior art.
Figure 2 is a perspective view of the intervertebral fusion cage, an embodiment of the present invention.
3 is a perspective view of the interbody fusion cage of FIG. 2 viewed from the front;
4 is an exploded perspective view of FIG. 2;
5 is a view from above of the body of the interbody fusion cage;
6 is a side view of the body of FIG. 5;
FIG. 7 is a view of the body of FIG. 5 seen from the front side; FIG.
8 shows a fixture of an intervertebral fusion cage.
9 is a view illustrating a peg portion in which a step is formed.
10 is a view showing the propulsion unit of FIG.
11 is a view showing a locking portion.
12 illustrates a side view of an intervertebral fusion cage.
13 is a view showing that the peg portion is pushed outward from the body portion due to the rearward movement of the pushing portion.
14 is a state diagram used in the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the intervertebral fusion cage with improved fixing force according to the present invention will be described in detail. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Unless otherwise defined, all terms in this specification are equivalent to the general meaning of the terms understood by those of ordinary skill in the art to which the present invention pertains, and in case of conflict with the meaning of the terms used herein Follow the definitions used in the specification.

2 is a perspective view of an intervertebral fusion cage, which is an embodiment of the present invention, FIG. 3 is a perspective view of the cage of FIG. 2, and FIG. 4 is an exploded perspective view of FIG. 2. 2 to 4, the intervertebral fusion cage 1 of the present invention is inserted between neighboring vertebrae, and promotes fusion of both vertebrae in contact with the intervertebral fusion cage 1. As it is, the intervertebral fusion cage (1) inside the patient's own bone, bone graft (Bone Graft), etc. is inserted, it is possible to further promote bone growth. The interbody fusion cage 1 includes a body portion 10 and a fixing portion 30.

The body portion 10 refers to a configuration having a shape that is inserted into the space between neighboring vertebral bones. The body portion 10 is configured to determine the overall shape of the intervertebral fusion cage (1), the intervertebral fusion cage (1) is easily inserted between the vertebral bones of the patient from which the disk or the like is removed, The rear end portion of the body portion 10 may be formed to be inclined to be configured to easily enter between narrow vertebral bones. In addition, it is preferable that the body portion 10 has a shape similar to the shape of the space between the vertebrae in order to accurately seat the intervertebral fusion cage 1 on a previously planned position without forming unnecessary spaces. And as a whole, as shown in the relatively small height, it may have a roughly rectangular parallelepiped shape. The body part 10 includes a peg part accommodating hole 11, a press part accommodating hole 13, a connection part accommodating hole 15, a coupling part accommodating hole 17, and a protrusion 19.

The peg part accommodating hole 11 is configured to accommodate a peg part 31 to be described later, and forms a hole penetrating one surface of the body part 10 to form a peg part in an empty space that is formed by the hole. Allow (31) to seat. As will be described later, the peg part 31 may be formed to be able to move up and down on the peg part accommodating hole 11. More preferably, the peg portion accommodating hole 11 has a shape for receiving the shaft portion 313 of the peg portion 31 to be described later, as shown in FIG. 5, and only the shaft portion 313 is the peg. It may be configured to be raised and lowered inside the receiving hole 11, the head portion 311 and the spike portion 315 to be described later other than the shaft portion 313 is to be accommodated inside the peg portion receiving hole (11) By configuring the peg part accommodating hole 11 to be positioned outside the peg part accommodating hole 11, the peg part 31 can be prevented from being separated from the peg part accommodating hole 11. The peg part accommodating hole 11 may be formed in a singular or plural number, and the number thereof is equal to the number of peg parts 31 to be included in the interbody fusion cage 1. Preferably it may be configured to be symmetrical to the upper side and the lower side relative to the center horizontal plane (CH) of the body portion 10, and to be symmetrically to the left and right relative to the center vertical surface (CV) of the body portion (10). Can be configured. As a result, a plurality of pegs 31 may be uniformly configured on the intervertebral fusion fusion cage 1 without being deflected to either side, thereby enabling firm fixation of the vertebral fusion fusion cage 1.

The pressing part accommodating hole 13 is configured to communicate with the peg part accommodating hole 11 and have a shape for accommodating the pressing part 331 to be described later. FIG. 6 is a view of the body of FIG. 5 from the side. Referring to FIG. 6, the pressure receiving hole 13 is in communication with the peg receiving hole 11 and is above the peg receiving hole 11. The peg part 31 seated in the body part 10 may provide a space in which the peg part 31 stays in a state before being protruded to the outside of the body part 10. First, the peg part 31 seated on the peg part accommodating hole 11 has a head portion 311 to be described later in an inner central portion of the press part accommodating hole 13. If the plurality of pegs 31 are symmetrically formed on the upper and lower sides, all of the head parts 311 of the upper and lower pegs 31 may be gathered in the inner central portion of the pressing part accommodating hole 13. . In this initial state, when the pressing part 331, which will be described later, moves backward by an external force, the head part 311 of the peg part 31 collected in the inner central part of the pressing part accommodating hole 13 is pushed up and the peg part is moved. 31 can be pushed out of the body portion 10, the peg portion 31 pushed out of the body portion 10 is embedded in the vertebral bone of the patient to interbody fusion cage (1) It is possible to increase the holding power of. For this series of operations, the pressing portion receiving hole 13 is preferably in communication with the peg portion receiving hole (11). In addition, on the intervertebral fusion cage (1) is provided a bone graft hole (H) which is a space for inserting the patient's autogenous bone. By inserting the patient's autogenous bone or bone graft on the bone graft hole (H), the patient's autogenous bone growth promotion can be induced from the intervertebral fusion cage (1), the pressure receiving hole (13) It may also be in communication with the bone graft hole (H) to facilitate the bone growth of the patient and facilitate the bone growth observation.

The connection part accommodating hole 15 refers to a configuration in communication with the pressure part accommodating hole 13 and having a shape for accommodating the connection part 333. As will be described later, the connection portion 333 may be a linear movement within a predetermined range, the connection portion receiving hole 15 has a space that can accommodate the connection portion 333 in view of the movement range of the connection portion 333. Will be provided. At both side ends of the connecting portion 333, the pressing portion 331 may be extended in the rearward direction of the interbody fusion cage 1, the connecting portion receiving hole 13 is the pressing to receive the pressing portion 331 By communicating with the auxiliary receiving hole 13, it is preferable not to cause interference on the movement path of the driving unit 33 to be described later. The connection part accommodating hole 15 should be capable of promoting the movement of the pressing part 331 coupled to the connection part 333 while the connection part 333 is linearly moved by receiving an external force. The hole 15 is preferably configured to be coupled to the coupling part receiving hole 17 to be described later to receive the propulsion force through the coupling part receiving hole 17.

The coupling part accommodating hole 17 refers to a configuration in communication with the connection part accommodating hole 15 and having a shape accommodating the coupling part 335. 7 is a view of the body portion of FIG. 5 from the front side, referring to FIG. 7, the coupling portion 335 to be described below is preferably rotated in combination with a separate surgical instrument (S) to the front and rear by this rotation. The connection part 333 to be in contact with the coupling part 335 is able to move forward by receiving a driving force from the coupling part 335. For this operation, the coupling part accommodating hole 17 for accommodating the coupling part 335 should be configured, and in order to transfer the driving force of the coupling part 335 to the connection part 333, the accommodation part 333 is accommodated. The connection part accommodating hole 15 is preferably in communication with the coupling part accommodating hole 17. With respect to the number of the coupling part accommodating holes 17 is not limited to any particular concept, but preferably to facilitate the operation and to push the plurality of pressing parts 331 in a single operation, shown As described above, the coupling part accommodation hole 17 may be configured to extend in the front direction from the center of the connection part accommodation hole 15. As will be described later, a thread 335a is formed on the outer circumferential surface of the coupling part 335 and may be configured to be moved forward by one direction rotation and backward by another direction rotation. A thread 17a having a shape complementary to the thread 335a of the coupling part 335 may be formed in the coupling part accommodation hole 17 so that the screw connection can be screwed with the 335a.

The protruding portion 19 indicates a configuration protruding on the upper and lower surfaces of the body portion 10. In other words, the protrusion 19 is formed on the upper and lower surfaces of the body portion 10 in contact with the vertebral bone, the shape to secure the fixing force of the intervertebral fusion cage 1 while reducing damage to the bone. It may be configured in the form having. When the intervertebral fusion cage 1 is inserted between the vertebral bones of the patient, the vertebral fusion cage 1 should be seated as it is on the planned position until the bone grows, and the protrusions on the upper and lower surfaces of the body part 10. (19) secures a strong fixation force between the intervertebral fusion cage (1) and the vertebral bones, thereby preventing the problem of the intervertebral fusion cage (1) being out of position due to movement of the patient, impact from the outside, and the like. You can do it. Preferably, the protruding portion 19 is formed above the height of the spike portion 315 to be described later, the spike portion 315 in the process of inserting and pushing between the intervertebral fusion cage 1 between the vertebral bone to be treated ) Can prevent the spine from getting caught.

8 is a view showing the fixing portion of the intervertebral fusion cage. Hereinafter will be described with reference to FIG.

The fixing portion 30 is coupled to the body portion 10 when the body portion 10 is positioned when the portion protrudes in the outward direction of the body portion 10 is inserted into the spinal bone. The intervertebral fusion cage (1) is also inserted between the adjacent vertebral bones to be accurately seated in the position planned by the preoperative surgeon, but it is important to maintain the original position intact until complete fusion of the vertebral bone is achieved. It is also important. If the intervertebral fusion cage (1) that is expected to promote bone growth inside the patient's body is out of position during the physical activity of the patient after surgery may be a problem such as postoperative sequelae, reoperation progress. Therefore, the present invention can achieve the initial position maintenance of the interbody fusion cage (1) through the configuration of the fixing portion (30). The fixing part 30 includes a peg part 31 and a pushing part 33.

The peg part 31 is configured to be coupled to the body part 10 so as to move up and down, and a plurality of peg parts 31 may be configured on the body part 10. Although not limited to the embodiment in which the peg portion 31 is composed of a singular dog, the peg portion 31 is preferably composed of a plurality in terms of being inserted into the vertebral bone to increase the fixing force of the intervertebral fusion cage (1). Do. When the peg part 31 is configured in plural, it may be more preferable that each peg part 31 is configured to be symmetrical in terms of securing an even fixation force of the upper, lower, left, and right sides of the intervertebral body fusion cage 1. Above all, the interbody fusion cage 1 is in contact with the upper and lower surfaces of the vertebral bone, so that the peg portion 31 is preferably secured to both sides of the adjacent upper and lower vertebral bones. The upper and lower sides may be configured based on the central horizontal plane CH of the body part 10. In addition, peg portions 31 respectively formed on the upper side and the lower side of the body portion 10 to achieve a uniform fixation force at each point of the intervertebral fusion cage 1 have a central horizontal plane CH of the body portion 10. It is preferably configured to be symmetrical with each other as a reference. The upper and lower pegs 31 are synchronized with each other to simultaneously lift or lower the movement. Detailed description thereof will be described later. In addition, the peg part 31 is preferably symmetrically to the left and the right side with respect to the center vertical surface CV of the body part 10 in order to implement a fixed force to the left and right while increasing the fixing force to one side vertebral bone. Can be configured. The left and right pegs 31 are synchronized with each other to simultaneously lift or lower the movement. Therefore, it is preferable to include the above-described contents so that the upper, lower, left and right peg portions 31 are synchronized so that they can be simultaneously moved up and down by external force while being symmetrical with each other. The peg part 31 includes a head part 311, a shaft part 313, and a spike part 315.

The head portion 311 is configured to be in direct contact with the propulsion shaft of the propulsion portion 33, and converts the horizontal linear movement of the propulsion portion 33 into a vertical linear movement. As will be described later, the propulsion unit 33 can be horizontally linear movement by the external force, the peg portion 31 is inserted into the peg portion receiving hole 11 is to be a vertical movement, the lifting bar, For the movement of the peg part 31, the head part 311 functions to convert the horizontal linear motion into a vertical linear motion. The shape of the head portion 311 is not limited to any particular concept, but may preferably be configured as a hemispherical shape having a curved surface. The hemispherical head portion 311 is in contact with the pressing portion 331 of the pushing portion 33 to be described later, the upper and lower head portion 311 which is in contact with the pressing portion 331 when the pressing portion 331 is moved forward It is pushed up along the inclined surface of the pressing unit 331, the slope of the tangential is gradually increased through the hemispherical head portion 311, it is possible to easily lift the peg portion 31.

The shaft portion 313 refers to a configuration in which one end is extended vertically while being coupled to the head portion 311. Preferably, the head portion 311 is formed in a hemispherical shape, the convex curved surface is in contact with the pressing portion 331, the flat opposite surface is in contact with the shaft portion 313. Referring to the contents shown in FIG. 9, the shaft portion 313 may be vertically extended as it is slightly reduced in size than the size of a flat bottom surface. If the shaft portion 313 is not reduced in diameter than the joint surface size with the head portion 311, when the peg portion 31 is pushed up through the pressing portion 331, there is no caught portion and thus the peg portion 31 is removed. It is not possible to determine the outer projection limit of. Therefore, the size of the cross section of the shaft portion 313 is configured to be smaller than the size of the joint surface of the head portion 311, so that the head portion 311 is the peg at the critical point when the peg portion 31 is elevated It is preferable not to pass through the auxiliary receiving hole (11). As described above, the peg part accommodating hole 11 has a shape for accommodating the shaft part 313, and only the shaft part 313 is configured to move up and down inside the peg part accommodating hole 11. To this end, the other end of the shaft portion 313 connected to the spike portion 315 to be described later, the joint surface of the spike portion 315 is formed larger than the other end of the shaft portion 313 is the peg portion receiving hole 11 By preventing the spike portion 315 from entering the inside, the inside acceptance limit of the peg portion 31 may be determined. In summary, the shaft portion 313 may be configured to be smaller in diameter than the joint surface size of the head portion 311 and the spike portion 315 to form a step.

The spike portion 315 refers to a configuration that forms an inclined surface while being coupled to the other end of the shaft portion 313. The spike portion 315 is a component that is directly embedded in the vertebral bone to generate a fixing force, to form an inclined surface, it is possible to facilitate the insertion of the spinal bone. With respect to the shape of the spike portion 315, it is not limited to any particular concept, but may preferably be configured to have a conical shape. Preferably, the spike portion 315, which is formed in a conical shape, has a peak inserted into the vertebral bone, and a flat bottom surface comes into contact with the other surface of the shaft portion 313. The shaft portion 313 may form a stepped portion having a size smaller than that of the flat bottom surface of the spike portion 315. Only the shaft part 313 may be accommodated inside the peg part accommodating hole 11, and the spike part 315 having a bottom surface larger than a cross section of the shaft part 313 may be the peg part accommodating hole. By engaging on (11), the inside acceptance limit of the peg part 31 which rises and falls is determined.

The propulsion part 33 is configured to raise and lower the peg part 31, and preferably, may be subjected to an external force to perform a horizontal linear motion. 8 to 10, the head part 311 is formed to be orthogonal to the propulsion shaft based on the propulsion shaft, which is the movement axis of the propulsion unit 33 performing a horizontal linear movement, and a propulsion unit to be described later ( The vertical and downward vertical movement is possible by the pressing unit 331 horizontally moving while being in contact with the pressing unit 331 vertically. The shape of the propulsion part 33 is not limited to a specific concept. Preferably, when the peg part 31 is formed in plural, the plurality of peg parts 31 are synchronized to move up and down simultaneously. It may have a shape so that it can be. Specifically, if the peg portion 31 is formed to be symmetrically spaced apart from the left and right at a predetermined distance, it may include a configuration having a length equal to the separation distance of the peg portion 31 on both sides. The propulsion part 33 includes a pressing part 331, a connection part 333, a coupling part 335, and a locking part 337.

The pressing part 331 enters between the head part 311 of the upper and lower peg part 31 to synchronize the upper and lower peg parts 31 and moves the head part 311 to the outside of the body part 10. Speak with the composition. The shape of the pressing unit 331 is not limited to any particular concept, but preferably, the direction is set at the same angle θ based on the central horizontal plane CH of the end of the pressing unit 331. Alternatively, it may be configured to include a pair of sloped, inclined surfaces. As described above, the head portion 311 which is in contact with the pressing portion 331 may be preferably formed in a hemispherical shape having a curved surface, in contact with the curved surface of the head portion 311 in the rearward direction. The head portion 311 is pushed outwardly of the body portion 10 by the moving pressing portion 331, and the shaft portion 313 coupled with the head portion 311 is raised and lowered. The spike portion 315 coupled with the shaft portion 313 may be embedded in the vertebral bone. Then, if the pressing portion 331 is moved in the front direction, the spike portion 315 embedded in the vertebral bone is fixed to the vertebral bone while maintaining the state. The pressing portion 331 is accommodated in the pressing portion receiving hole 13 communicated with the peg portion receiving hole 11 may be a horizontal horizontal movement within a predetermined range. The pressing portion 331 is a configuration for transmitting an external force to the peg portion 31, the number may vary depending on the number and position of the peg portion 31. The pressing part 331 is the upper and lower peg parts 31 symmetrical with only a single pressing part 331 if the peg part 31 is symmetrical upward and downward with respect to the center horizontal plane CH of the body part 10. ) Can be raised and lowered at the same time, but if the peg portion 31 is symmetrical to the left and right with respect to the center vertical surface CV of the body portion 10, the left and right peg portions 31 are symmetrical with only a single pressing portion 331. Cannot be raised and lowered at the same time. Therefore, it is necessary to configure the pressing unit 331 separately on each of the left and right sides, and consequently, the number of the pressing unit 331 can be seen to be dependent on the number of the pair of peg portions 31 forming the left and right symmetry. .

The connection part 333 refers to a configuration for connecting the pressing parts 331 formed on each of the left and right sides for synchronization of the left and right peg parts 31. As described above, the pressing portion 331 is a single pressing portion 331, a pair of peg portions 31 symmetrically upward and downward, the pressing portion (3) between the head portion 311 of both peg portions 31 Through entering the 331, the upper and lower peg portion 31 can be pushed up at the same time, but a pair of peg portions 31 symmetrically to the left and right bar bar, so that the pressing portion 331 is configured separately on both left and right sides. Should be. In this case, in order to synchronize the peg part 31 which is symmetrical with respect to the center vertical surface CV of the body part 10, a configuration for connecting the pressing parts 331 spaced apart from the left and right sides is necessary, and the connection part ( 333 serves to connect the pressing portion 331. With respect to the shape of the connection portion 333 is not limited to any particular concept, it is preferable that it is composed of more than the length that can reach the peg portion 31 on the left side and the peg portion 31 on the right side.

The coupling portion 335 refers to a configuration for transmitting a driving force in contact with the connection portion 333. The coupling part 335 is configured to directly move the pressing part 331 coupled to the connection part 333 by pushing the connection part 333. Preferably, the connecting portion 333 is configured to be long in the transverse direction to connect the pressing portion 331 on the left side and the pressing portion 331 on the right side, for even transmission of the driving force, the coupling portion 335 May be configured to be in contact with the center of the connection portion 333. With respect to the shape of the coupling portion 335 is not limited to any particular concept, but preferably, may include a thread 335a protruding along the outer circumferential surface. Propulsion through the coupling portion 335 should be made in a planned position without shaking, the coupling portion 335 accommodated in the coupling portion receiving hole 17 is formed with a screw thread 335a, the screw thread (17a) is formed On the coupling part accommodating hole 17, the screw thread 335a of the coupling part 335 and the screw thread 17a of the coupling part accommodating hole 17 are moved forward by one direction rotation, It may be configured to be movable backward by the rotation in the other direction. Referring to the coupling between the coupling portion 335 and the connecting portion 333, the coupling portion 335 is a configuration that performs a horizontal linear motion with a rotational movement, the connection portion 333 is a horizontal straight line without rotational movement It is preferable that the coupling part 335 and the connection part 333 are coupled so that the rotational force of the coupling part 335 is not transmitted to the connection part 333. As such a coupling method, various techniques known or known in the art may be applied.

The locking portion 337 is formed to protrude forward from the center of the connecting portion 333 and is coupled to the surgical instrument (S) refers to a configuration for moving the connecting portion 333 back. 10 is a view showing a locking portion, which will be described below with reference to FIG. 11. The separate surgical instrument S, which is fastened to the coupling part 335 to rotate the coupling part 335, rotates in one direction to realize a forward movement of the coupling part 335, and the coupling part 335 Due to the forward movement of the connecting portion 333 in contact with the coupling portion 335 is also pushed forward. However, in the state in which the connection part 333 is pushed forward by a predetermined distance, when the coupling part 335 is rotated in the other direction by reversely rotating the surgical instrument S, the connection part 333 is moved. The external force is not transmitted to), leaving the connection part 333 intact and causing only the coupling part 335 to move. Therefore, in order to prevent such a problem, by forming the engaging portion 337 protruding on the connecting portion 333, when the surgical instrument (S) to rotate in the other direction, the surgical instrument (S) is the engaging portion 337 By coupling with), it is possible to enable the front side movement of the connecting portion 333. The shape of the locking portion 337 is not limited to any specific concept, and the shape of the locking portion 337 may be variously determined in relation to a surgical instrument S capable of performing the above-described function. Can be. Like the coupling part 335, the locking part 337 may be formed on the central portion of the connection part 333 for even transmission of the driving force.

Figure 12 is a view showing the side of the interbody fusion cage, Figure 13 is a view showing that the peg portion is pushed in the outward direction of the body portion due to the rearward movement of the propulsion portion, Figure 14 is a use state diagram of the present invention. 12 to 14, the interbody fusion cage 1 is inserted into the space between the vertebral bones B having a surgical instrument S fixed to the coupling part 335. Body portion 10 of the intervertebral fusion cage 1 is formed so that the rear end is inclined can be easily grabbed between the narrow vertebral bone (B). When the surgeon correctly positions the interbody fusion cage 1 on the planned position before surgery, a predetermined fixing force may be secured by the protrusions 19 protruding from the upper and lower surfaces of the body part 10. However, the fixing force by the protrusions 19 may be insufficient to prevent the problem of preventing in-situ deviation of the intervertebral fusion cage 1. Therefore, the surgeon performs the operation of rotating the surgical instrument (S) to impose a strong fixing force when the interbody fusion cage (1) is seated in place. The surgical instrument (S) is coupled to the coupling portion 335, the thread 335a is formed, the coupling portion 335 by the rotation of the coupling portion 335 is the rearward direction of the interbody fusion cage (1) It will move horizontally. The coupling part 335 is in contact with the connection part 333, so that the connection part 333 is also moved by the movement of the coupling part 335. Pressing portions 331 are configured at both ends of the connecting portion 333, and the pressing portion 331 is symmetrically formed on the upper and lower sides due to the movement of the connecting portion 333. (10) to push outward. As a result, the peg part 31 is embedded in a neighboring vertebral bone B to increase the fixing force of the intervertebral fusion cage 1.

The foregoing detailed description illustrates the present invention. In addition, the above-mentioned content shows and describes preferred embodiment of this invention, and this invention can be used in various other combinations, changes, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosures described above, and / or the skill or knowledge in the art. The described embodiments illustrate the best state for implementing the technical idea of the present invention, and various modifications required in the specific application field and use of the present invention are possible. Thus, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

1: interbody fusion cage
10: body part 11: peg part receiving hole
13: Pressure receiving hole 15: Connection part receiving hole
17: coupling part receiving hole 19: protrusion
30: fixed part 31: peg part
311: head portion 313: shaft portion
315: spike portion 33: propulsion unit
331: pressure portion 333: connection portion
335: coupling portion 337: locking portion

Claims (17)

A body portion having a bone graft hole in a central portion thereof, and a fixed portion inserted into the vertebral bone when a portion of the body portion is coupled to the body portion and protrudes outwardly of the body portion when the body portion is positioned,
The fixing part includes a peg part coupled to the body part to enable the lifting and lowering, and a propulsion part to raise and lower the peg part.
The peg portion is formed on the left and right sides of the body portion with at least a portion of the bone graft hole therebetween,
The propulsion unit includes a left and right pressing unit for pushing the peg portions formed on the left and right sides of the body unit to the outside of the body unit, a connecting unit connecting the left and right pressing units for synchronization of the left and right peg units, and a coupling unit for rotating linear movement,
The pressing part and the connection part are separated from the coupling part, and the peg part on the left and right sides can be lifted up and down only by the linear motion by the coupling part performing a rotational linear motion.
The pressurizing portion and the connecting portion, the 'c' shaped to minimize the intrusion of the connecting portion into the bone graft hole, characterized in that the fixing force between the interbody fusion cage. delete The intervertebral fusion cage according to claim 1, wherein the peg portion includes a head portion that is in contact with the propulsion axis of the propulsion portion. The intervertebral fusion cage according to claim 3, wherein the peg part includes a shaft part extended vertically while being coupled to form the step with the head part. The intervertebral fusion cage according to claim 4, wherein the peg portion includes a spike portion coupled to form the stepped portion with the shaft portion to form an inclined surface. The intervertebral fusion cage according to claim 5, wherein the peg part is symmetrically configured on an upper side and a lower side with respect to the center horizontal plane of the body part, and the upper and lower pegs are synchronized with each other. The intervertebral fusion cage according to claim 6, wherein the peg part is symmetrically configured on the left and right sides of the body based on the center vertical surface of the body part, and the left and right peg parts are synchronized to move up and down. The intervertebral fusion cage according to claim 3, wherein the head portion has a hemispherical shape having a curved surface. delete The intervertebral fusion cage according to claim 1, wherein the pressing part includes a pair of inclined surfaces that are inclined at different angles at the same angle with respect to the central horizontal plane of the end portion. The intervertebral fusion cage according to claim 1, wherein the connection part further comprises a locking part protruding forwardly. The intervertebral fusion cage according to claim 1, wherein the coupling part includes a screw thread protruding along an outer circumferential surface. delete The method of claim 1, wherein the body portion, the peg portion receiving hole having a shape for accommodating the peg portion, the pressing portion accommodating hole having a shape in communication with the peg portion accommodating hole and receiving the pressing portion, and the pressing portion accommodating hole and An interlocking fusion cage having a fixed force, characterized in that it comprises a connection part receiving hole in communication with each other and having a shape for receiving the connection part, and a connection part receiving hole in communication with the connection part receiving hole and for receiving the coupling part. 15. The interbody fusion cage according to claim 14, wherein the peg portion accommodating hole accommodates the shaft portion of the peg portion. 15. The intervertebral fusion cage of claim 14, wherein the body portion further includes protrusions protruding from the upper and lower surfaces. 17. The intervertebral fusion cage of claim 16, wherein the protrusion is formed at a height greater than or equal to the height of the spike.

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