KR20230033084A - Intervertebral Body Fusion Prosthesis With Porous Structure of Shell Type - Google Patents

Abstract

The present invention relates to an intervertebral body fusion prosthesis having a shell-type porous structure, and more specifically, to an intervertebral body fusion prosthesis having a shell-type porous structure, which replaces poly ether ether ketone (PEEK) that is a polymer material with a similar strength to that of bone but with a disadvantage of not adhering to bone, such that even if the intervertebral body fusion prosthesis is made of bio-metallic materials such as titanium and titanium alloy, a strength of the intervertebral body fusion prosthesis can be similar to that of bone due to a bone growth area of a porous structure formed in a shell type, thereby preventing occurrence of bone subsidence due to intervertebral body fusion prosthesis having a higher strength than that of bone.

Description

Intervertebral Body Fusion Prosthesis With Porous Structure of Shell Type}

The present invention relates to an intervertebral body fusion prosthetic material having a shell-type porous structure, and more particularly, to replace PEEK (Poly Ether Ether Ketone), a polymer material having strength similar to bone but having the disadvantage of not sticking to bone. Even if the intervertebral body fusion prosthesis is composed of biometallic materials such as titanium and titanium alloy, the strength of the intervertebral body fusion prosthesis is similar to that of bone due to the bone growth part of the porous structure formed in the shell type. The present invention relates to an intervertebral body fusion prosthesis having a shell-type porous structure that prevents bone subsidence caused by the intervertebral body fusion prosthesis having higher strength than bone.

The spine is the longitudinal axis of the body and consists of 7 cervical vertebrae, 12 thoracic vertebrae, 5 lumbar vertebrae, 5 sacrum vertebrae, and 4 coccyx vertebrae. vertebrae; Also called an intervertebral disc, it consists of a disc in the form of a disk of cartilage that connects vertebrae to vertebrae.

In general, a spinal disc absorbs the load and shock of the body between the vertebrae, acts as a buffer to distribute the shock like a spring, holds the vertebrae so that they do not disintegrate, and separates the two vertebrae so that the spinal nerves are not compressed. It smoothes the range of the spinal joint hole and plays a role in facilitating the movement of each of the vertebrae.

Such a human spinal disc usually consists of a structure of an annulus fibrosus and a nucleus pulposus. If water in a water balloon is a nucleus pulposus, the annulus fibrosus corresponds to a rubber balloon containing water.

If you suffer from degenerative disc disease, the movement of the annulus or the ability to contain the nucleus pulposus is weakened, and the water content of the spinal disc is reduced, resulting in spinal stenosis, osteophyte formation, disc herniation ( Diseases such as Lumbar Herniated Intervertebral Disc) and nerve root compression may occur.

As a method for treating diseases related to these intervertebral discs, an operation is performed in which an intervertebral disc of a damaged human body is removed, and then an intervertebral body fusion implant (Cage) is inserted into the space between two adjacent vertebral bodies.

The intervertebral body fusion prosthesis serves to restore the height of the intervertebral body and the curvature of the spine, and restores the biomechanical stability of the spine by structurally supporting the vertebral body.

The intervertebral body fusion prosthesis has an appropriate thickness and anatomic shape to restore the original height of the intervertebral disc, and a hole is formed on the inside to insert a bone graft to grow bone. It facilitates and has a shape having a mounting hole for being mounted on an insertion tool.

Depending on the direction in which the cage is inserted during surgery, Posterior Lumbar Interbody Fusion (PLIF), Transforaminal Lumbar Interbody Fusion (TLIF), Anterior Lumbar Interbody Fusion (ALIF), and Lumbar Spine It is divided into Direct Lateral Interbody Fusion (DLIF).

1 is a view showing a conventional intervertebral body fusion prosthesis 90, which is disclosed in Korean Patent Registration No. 10-1806140 (2017.12.01.).

Referring to FIG. 1, the conventional intervertebral body fusion prosthetic material 90 is inserted between neighboring vertebrae to generate elastic force to prevent subsidence, and the bone fusion unit 91 and the main frame 93 include

As shown in FIG. 1, the bone union unit 91 has a structure in which units composed of at least one or more circular rings are repeated in a predetermined pattern.

The main frame 93 includes a pair of upper bars 931, a pair of lower bars 932, an upper insertion bar 933, a lower insertion bar 934, and the upper insertion bar 933. ) and the front finishing piece 935 connected to the front end of each of the lower insertion bar 934 and the front end of each of the upper insertion part 933 and the lower insertion bar 934 are connected to each other. A first connecting bar 936 connected to the upper and lower edges of the front closing piece 935 and the front ends of each of the upper bar 931 and the lower bar 932 are connected to each other, The second connecting bar 937 disposed in parallel with the first connecting bar 936 and the rear ends of each of the upper bar 931 and the lower bar 932 are connected to each other, and the second connecting bar 937 It is configured to include a third connecting bar 938 disposed parallel to.

That is, when the entire skeleton of the conventional intervertebral body fusion prosthesis 90 is formed by the main frame 93, the empty space formed by the main frame 93 is filled by the bone fusion unit 91. made in the form

However, in the case of such a conventional intervertebral body fusion prosthesis 90, the empty space inside the main frame 93 is filled by the bone fusion unit 91, and the intervertebral body fusion prosthesis 90 A problem arises in which the overall strength is increased.

In the conventional intervertebral body fusion prosthesis 90, since the bone union unit 91 is formed as a unit body in a circular ring that exhibits elastic force, the intervertebral body fusion prosthesis 90 is made of a biometallic material such as titanium. Even if configured, it is claimed that the sedimentation phenomenon is prevented by the elastic force, but the sedimentation phenomenon is not caused by the presence or absence of the elastic force, but by whether the strength of the intervertebral body fusion prosthesis 90 itself is similar to the strength of the adjacent bone, so, When the inside of the main frame 93 is filled with the bone union unit 91 formed of a biometallic material such as titanium, the overall strength of the intervertebral body fusion prosthesis 90 is greatly increased, and bone sedimentation inevitably occurs.

Moreover, according to the intervertebral body fusion prosthetic material 90, since an internal space into which an autogenous bone graft can be inserted is not formed, bone by the bone graft inserted into the intervertebral body fusion prosthetic material 90 As growth promotion cannot be expected, the bone fusion rate slows down.

Accordingly, the related industry secures the maximum internal space of the intervertebral fusion prosthesis so that even if the intervertebral fusion prosthesis is made of biometallic materials such as titanium, the strength of the intervertebral fusion prosthesis does not increase, so that phenomena such as bone subsidence do not occur. There is a demand for the introduction of a new technology that can sufficiently fill the empty space with the bone graft and achieve rapid bone union with the sufficiently filled bone graft.

Korean Registered Patent Publication No. 10-1806140 (2017.12.01.)

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

An object of the present invention is to improve the strength of the intervertebral body fusion prosthesis due to the bone growth part of the porous structure formed in the shell type even if the intervertebral body fusion prosthesis is made of biometallic materials such as titanium and titanium alloy. As it can have strength similar to that of bone, it is to prevent bone subsidence caused by an intervertebral body fusion prosthesis having higher strength than bone.

Another object of the present invention is to replace PEEK (Poly Ether Ether Ketone), a polymer material that has strength similar to bone but has the disadvantage of not sticking to bone, and can be used as a biometal material such as titanium and titanium alloy. It is to make it possible to easily construct an intervertebral body fusion prosthesis having a similar strength.

Another object of the present invention is to form a bone growth part in a shell type to increase the porosity in the intervertebral body fusion prosthesis, thereby promoting bone ingrowth and achieving rapid bone fusion. is to make it happen.

Another object of the present invention is to construct a shell-type first bone growth part on the opening of the frame part forming the skeleton of the intervertebral body fusion prosthesis, so that a larger amount of bone graft is formed on the inner space formed by the frame part. (Bone Graft) can be filled in, and the bone graft (Bone Graft) inserted into the internal space by the first bone growth part is prevented from escaping to the outside of the intervertebral body fusion prosthesis and being lost.

Another object of the present invention is to configure the first bone growth portion not to exceed the outermost profile of the opening formed by the frame portion, thereby preventing the relatively weak first bone growth portion from being damaged.

Another object of the present invention is to protect the first bone growth portion, block the generation of fine particles (Porous Particle) due to damage to the first bone growth portion, and penetrate the patient's tissues, blood vessels, etc. to cause inflammation. It is to prevent problems that can cause abnormal reactions such as reactions.

Another object of the present invention is to configure the first bone growth part so as not to exceed the innermost profile of the opening formed by the frame part, while sufficiently securing an internal space into which a bone graft can be inserted, This is to prevent an increase in the strength of the fusion shaping material.

Another object of the present invention is to construct a penetrating portion penetrating from one side of the first bone growth portion to the other side on the first bone growth portion, and to insert a bone graft into the inner space of the intervertebral body fusion prosthesis through the penetrating portion. It is to make it easy to insert.

Another object of the present invention is to construct a first through portion on the first bone growth portion forming the upper side of the intervertebral body fusion prosthesis, and to form the first bone growth portion forming the lower side of the intervertebral body fusion prosthesis. A second through-hole facing the first through-hole is formed so that a large amount of bone graft can be densely filled into the inner space of the intervertebral body fusion prosthesis through the first through-hole and the second through-hole. is to do

Another object of the present invention is to configure a first rim frame part of a non-porous structure formed along the inner circumferential surface of the first through part and a second rim frame part of a non-porous structure formed along the inner circumferential surface of the second through part, It is to protect the porous structure exposed in the process of filling the inner space of the intervertebral body fusion prosthesis through the penetrating part and the second penetrating part from being damaged by external force.

Another object of the present invention is to reinforce the strength of the intervertebral body fusion prosthesis by constructing a shell-type second bone growth portion vertically connecting the first rim frame and the second rim frame, so that the intervertebral body fusion prosthesis is subjected to vertical load. to have resistance to

Another object of the present invention is to configure the second bone growth portion to have a larger void than the first bone growth portion, so that a bone graft inserted through the penetrating portion passes through the second bone growth portion to allow the second bone growth portion to pass through the second bone growth portion. It is to be easily filled into the space between the bone growth unit and the first bone growth unit.

Another object of the present invention is to configure the second bone growth part not to exceed the outermost and innermost profiles formed by the first rim frame part and the second rim frame part, so that the inside where the bone graft can be inserted. It is to prevent the strength of the intervertebral body fusion prosthetic material from increasing while securing a sufficient space.

Another object of the present invention is to prevent the front side of the intervertebral fusion prosthesis from being damaged when the intervertebral fusion prosthesis is pushed into the space between neighboring vertebrae by constructing a head frame on the front side of the intervertebral fusion prosthesis. is to do

Another object of the present invention is to construct a third bone growth part connecting the head frame part and the second bone growth part, and a fourth bone growth part connecting the propulsion frame part and the second bone growth part, thereby forming an intervertebral body fusion prosthetic material. In the process of propulsing to the space between the vertebrae, the flow of external force due to friction with the surroundings not only continues from the head frame through the body frame to the propulsion frame, but also from the head frame to the third bone growth portion, By passing through the second bone growth part and the fourth bone growth part in order and leading to the propulsion frame part, the intervertebral body fusion prosthesis is prevented from being damaged by external force during the propulsion process of the intervertebral body fusion prosthesis.

Another object of the present invention is to configure the third bone growth part and the fourth bone growth part to have a larger gap than the first bone growth part, so that the bone graft inserted through the penetrating part is able to penetrate the second bone growth part. and the third bone growth part and the fourth bone growth part formed in the space formed by the second bone growth part and the first bone growth part also pass through, so that the second bone growth part and the first bone growth part are formed. It is to ensure that the space is filled evenly.

Another object of the present invention is to construct a body fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis on the body frame, so that the intervertebral body fusion prosthesis is easily propulsed, while When the position of the intervertebral body fusion prosthesis is set, the initial fixing force of the intervertebral body fusion prosthesis can be secured by increasing the frictional force with the bone.

Another object of the present invention is to construct a first rim fixator and a second rim fixator formed obliquely protruding along the propulsion direction of the intervertebral body fusion prosthesis on the first rim frame part and the second rim frame part, respectively, so that the intervertebral body is fused. The propulsion of the prosthesis is made easy, but when the intervertebral body fusion prosthesis is positioned on a pre-planned position, the fixing force between the adjacent vertebrae and the intervertebral body fusion prosthesis increases, and before bone fusion occurs, It is to prevent problems such as deviation of the intervertebral body fusion prosthetic from the correct position.

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

According to one embodiment of the present invention, the present invention includes a frame portion of a non-porous structure forming a skeleton of an intervertebral body fusion prosthesis, and a bone growth portion of a porous structure formed in a plurality of voids, wherein the bone growth portion is a shell It is formed in a (shell) type and characterized in that it includes a first bone growth portion forming the outer surface of the intervertebral body fusion prosthesis.

According to another embodiment of the present invention, the frame part is characterized by forming an inner space, which is an empty inner space, and an opening, which is an open surface communicating the inner space with the outside of the intervertebral body fusion prosthesis .

According to another embodiment of the present invention, the first bone growth portion is formed on the opening.

According to another embodiment of the present invention, the first bone growth portion does not exceed the outermost profile of the opening.

According to another embodiment of the present invention, the first bone growth portion does not exceed the innermost profile of the opening.

According to another embodiment of the present invention, the intervertebral body fusion prosthetic material further comprises a penetrating portion, which is a hole formed to penetrate from one side of the first bone growth portion to the other side and communicates with the internal space. to be

According to another embodiment of the present invention, the penetrating part is formed to pass through the first bone growth part forming the upper side and the first bone growth part forming the lower side. It is characterized in that it comprises a second through portion formed.

According to another embodiment of the present invention, the first through-portion and the second through-portion are formed on positions facing each other.

According to another embodiment of the present invention, the frame portion includes a first rim frame portion formed along an inner circumferential surface of the first through portion and a second rim frame portion formed along an inner circumferential surface of the second through portion. characterized by

According to another embodiment of the present invention, the bone growth part includes a second bone growth part formed in a shell type and vertically connecting the first rim frame part and the second rim frame part. It is characterized by doing.

According to another embodiment of the present invention, the second bone growth part is characterized in that the size of the void is larger than that of the first bone growth part.

According to another embodiment of the present invention, the second bone growth portion does not exceed an outermost profile formed by the first rim frame portion and the second rim frame portion.

According to another embodiment of the present invention, the second bone growth portion does not exceed an innermost profile formed by the first rim frame portion and the second rim frame portion.

According to another embodiment of the present invention, the frame part includes a head frame part formed on the front side of the intervertebral body fusion prosthesis, and the bone growth part is formed in a shell type, and the head frame part and a third bone growth portion connecting the second bone growth portion.

According to another embodiment of the present invention, the third bone growth part is characterized in that the size of the void is larger than that of the first bone growth part.

According to another embodiment of the present invention, the frame part includes a propulsion frame part formed on the rear side of the intervertebral body fusion prosthesis, and the bone growth part is formed in a shell type, and the propulsion frame part and a fourth bone growth portion connecting the second bone growth portion.

According to another embodiment of the present invention, the fourth bone growth part is characterized in that the size of the void is larger than that of the first bone growth part.

According to another embodiment of the present invention, the frame unit includes a body frame unit connecting a head frame unit formed on the front side of the intervertebral body fusion prosthesis and a propulsion frame unit formed on the rear side of the intervertebral body fusion prosthesis, , The body frame portion is characterized in that it includes a body fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis.

According to another embodiment of the present invention, the first rim frame part includes a first rim fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis, and the second rim frame part comprises the It is characterized in that it includes a second rim fixture protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis.

The present invention can obtain the following effects by combining and using the above embodiments and configurations to be described below.

In the present invention, even if the intervertebral body fusion prosthesis is composed of a biometallic material such as titanium or titanium alloy, the strength of the intervertebral body fusion prosthesis is reduced to that of the bone due to the bone growth part of the porous structure formed in the shell type. As it can have similar strength, it has an effect of preventing bone subsidence caused by the intervertebral body fusion prosthesis having higher strength than bone.

The present invention replaces PEEK (Poly Ether Ether Ketone), a polymer material that has strength similar to bone but has the disadvantage of not sticking to bone, and biometal materials such as titanium and titanium alloy have strength similar to bone. An effect that allows the intervertebral body fusion prosthesis to be easily constructed having is derived.

The present invention forms the bone growth part in a shell type to increase the porosity in the intervertebral body fusion prosthetic material, thereby promoting bone ingrowth and achieving rapid bone fusion. there is

In the present invention, a shell-type first bone growth part is formed on the opening of the frame part forming the skeleton of the intervertebral body fusion prosthetic material, and a larger amount of bone graft is formed on the inner space formed by the frame part This has an effect of preventing the bone graft inserted into the internal space by the first bone growth part from escaping to the outside of the intervertebral body fusion prosthesis and being lost.

The present invention is configured such that the first bone growth portion does not exceed the outermost profile of the opening formed by the frame portion, thereby obtaining an effect of preventing damage to the first bone growth portion, which has relatively low strength.

The present invention protects the first bone growth portion, blocks the generation of fine particles (Porous Particle) due to damage to the first bone growth portion, and penetrates the patient's tissues, blood vessels, etc. to cause abnormalities such as inflammatory reactions. It has the effect of preventing problems that can cause a reaction.

The present invention is configured such that the first bone growth part does not exceed the innermost profile of the opening formed by the frame part, so that the internal space into which the bone graft can be inserted is sufficiently secured, and the strength of the intervertebral body fusion prosthesis is ensured. has the effect of preventing an increase in

The present invention configures a through portion passing through the other side from one side of the first bone growth portion on the first bone growth portion, so that a bone graft is easily inserted into the internal space of the intervertebral body fusion prosthesis through the through portion. It derives an effect that allows it to be put in.

The present invention configures the first through part on the first bone growth part forming the upper side of the intervertebral body fusion prosthesis, and the first through part on the first bone growth part forming the lower side of the intervertebral body fusion prosthetic material. By configuring the second through-portion opposite to, there is an effect of densely filling a large amount of bone graft on the inner space of the intervertebral body fusion prosthesis through the first through-hole and the second through-hole. .

The present invention comprises a first rim frame portion having a non-porous structure formed along the inner circumferential surface of the first through-portion and a second rim frame portion having a non-porous structure formed along the inner circumferential surface of the second through-portion, It has an effect of protecting the porous structure exposed in the process of filling the inner space of the intervertebral body fusion prosthesis from being damaged by external force through the second through-hole.

In the present invention, by configuring the second bone growth part of the shell type connecting the first rim frame part and the second rim frame part vertically, the strength of the intervertebral fusion prosthesis is reinforced so that the intervertebral fusion prosthetic material can resist vertical load. derive the effect that can be had.

In the present invention, the second bone growth portion is configured to have a larger gap than the first bone growth portion, so that a bone graft inserted through the through portion passes through the second bone growth portion and connects to the second bone growth portion. There is an effect that can be easily filled in the space between the first bone growth portion.

In the present invention, the second bone growth part is configured so that it does not exceed the outermost and innermost profiles formed by the first rim frame part and the second rim frame part, so that an internal space into which a bone graft can be inserted is sufficiently secured. While, it has an effect of preventing the strength of the intervertebral body fusion prosthesis from increasing.

The present invention derives an effect of preventing the front side of the intervertebral fusion prosthesis from being damaged when the head frame is configured on the front side of the intervertebral fusion prosthesis and the intervertebral fusion prosthesis is pushed into the space between neighboring vertebrae. do.

The present invention constitutes a third bone growth part connecting the head frame part and the second bone growth part, and a fourth bone growth part connecting the propulsion frame part and the second bone growth part, so that the intervertebral body fusion prosthetic material is formed between the vertebrae. In the process of propulsion into the space, the flow of external force due to friction with the surroundings not only leads from the head frame to the propulsion frame through the body frame, but also from the head frame to the third bone growth portion and the second bone By passing the growth part and the fourth bone growth part in order and continuing to the propulsion frame part, there is an effect of preventing the intervertebral body fusion prosthesis from being damaged by external force during the propulsion process of the intervertebral body fusion prosthesis.

In the present invention, the third bone growth part and the fourth bone growth part are configured to have a larger gap than the first bone growth part, so that the bone graft inserted through the penetrating part passes through the second bone growth part, The third bone growth part and the fourth bone growth part formed on the space formed by the second bone growth part and the first bone growth part also pass through, and the second bone growth part and the first bone growth part formed on the space formed by the It has the effect of allowing it to be filled evenly.

In the present invention, the intervertebral body fusion prosthesis is easily propulsed by constructing a body fixing device protruding obliquely along the direction of propulsion of the intervertebral body fusion prosthesis on the body frame part, while the intervertebral body fusion prosthesis is easily promoted. When the fusion prosthesis is positioned, the effect of increasing the frictional force with the bone to secure the initial fixing force of the intervertebral body fusion prosthesis is derived.

In the present invention, a first rim fixator and a second rim fixator are respectively formed on the first rim frame and the second rim frame to protrude obliquely along the propulsion direction of the intervertebral body fusion prosthesis, so that the propulsion of the intervertebral body fusion prosthesis is To make it easy, but when the intervertebral body fusion prosthesis is positioned on a pre-planned position, the fixing force between the adjacent vertebrae and the intervertebral body fusion prosthesis increases, and before bone fusion occurs, the intervertebral body fusion prosthesis There is an effect of preventing problems such as deviation of the ash from its original position.

1 is a view showing a conventional intervertebral body fusion prosthesis.
2 is a perspective view illustrating an intervertebral body fusion prosthesis having a shell-type porous structure according to an embodiment of the present invention.
3 is a front view of the intervertebral body fusion prosthesis of FIG. 2;
4 is a plan view of the intervertebral body fusion prosthesis of FIG. 2;
5 is an exploded perspective view of the intervertebral body fusion prosthesis of FIG. 2;
6 is a AA′ cross-sectional view of FIG. 2;
7 is a BB′ cross-sectional view of FIG. 2;
8 is a CC′ cross-sectional view of FIG. 2;
9 is a perspective view illustrating an intervertebral body fusion prosthesis having a shell-type porous structure according to another embodiment of the present invention.
10 is a use state diagram of the present invention.

Hereinafter, preferred embodiments of the intervertebral body fusion prosthesis having a shell-type porous structure according to the present invention will be described in detail with reference to the accompanying drawings. 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 there is a special definition, all terms in this specification are the same as the general meaning of the term understood by a person skilled in the art to which the present invention belongs, and if it conflicts with the meaning of the terms used in this specification, Follow the definitions used in the specification.

The intervertebral body fusion prosthesis (1) having a shell-type porous structure according to the present invention replaces PEEK (Poly Ether Ether Ketone), which is a polymer material that has strength similar to that of bone but has the disadvantage of not sticking to bone, and titanium (Titanium ), even if the intervertebral body fusion prosthesis is composed of biometallic materials such as titanium alloy, etc., the strength of the intervertebral body fusion prosthesis can have strength similar to that of bone due to the bone growth part of the porous structure formed in the shell type. Accordingly, bone subsidence caused by the intervertebral body fusion prosthesis, which has higher strength than bone, is prevented from occurring.

2 is a perspective view showing an intervertebral body fusion prosthesis 1 having a shell-type porous structure according to an embodiment of the present invention, and FIG. 3 is a front view of the intervertebral body fusion prosthesis 1 of FIG. 2, FIG. 4 is a plan view of the intervertebral body fusion prosthesis 1 of FIG. 2 . Referring to FIGS. 2 to 4 , the intervertebral body fusion prosthesis 1 having the shell-type porous structure is ), a bone growth portion 30, and a penetrating portion 50.

The frame portion 10 refers to a configuration of a non-porous structure forming a skeleton of the intervertebral body fusion prosthetic material 1 . As shown in FIG. 5, the frame part 10 forms the overall framework of the intervertebral body fusion prosthetic material 1, and an empty inner space 101 is formed inside the frame part 10. And, the opening 103, which is an open surface that communicates the inner space 101 with the outside of the intervertebral body fusion prosthesis 1, may be formed on the upper, lower, left, and right sides of the frame part 10, respectively. there is. The opening 103 may not be formed on the front side of the frame part 10 because the head frame part 11, which will be described later, forms a solid surface having a non-porous structure as shown in FIG. 5 . However, this does not exclude an embodiment in which the opening 103 is formed on the head frame portion 11 to be described later.

Referring to FIG. 5 , the frame unit 10 includes a head frame unit 11, a propulsion frame unit 13, a body frame unit 15, and a rim frame unit 17.

The head frame part 11 is a non-porous frame formed on the front side of the intervertebral body fusion prosthesis 1, and as shown in FIG. 5, by forming a solid structure, the intervertebral body fusion beam The front part of the intervertebral body fusion prosthesis 1 can be protected while the shape member 1 is pushed into the space between the neighboring vertebrae. Preferably, the head frame portion 11 may have a substantially truncated cone shape.

The propulsion frame part 13 refers to a frame having a non-porous structure formed on the rear side of the intervertebral body fusion prosthesis 1 . A gripping groove for gripping the intervertebral body fusion prosthesis 1 may be formed on the propulsion frame part 13, and a surgical instrument is coupled to the gripping groove to hold the intervertebral body fusion prosthesis 1 to the vertebrae. It can be easily inserted into the space between them. As such, since the rear side of the intervertebral body fusion prosthesis 1 is a part directly subjected to external force by the surgical instrument, it is formed in a non-porous structure in order to protect the intervertebral body fusion prosthesis 1 during the propulsion process. The propulsion frame part 13, which is relatively strong in strength compared to the porous structure, forms the rear surface of the intervertebral body fusion prosthetic material 1.

The body frame part 15 includes the head frame part 11 formed on the front side of the intervertebral body fusion prosthesis 1 and the propulsion frame part 13 formed on the rear side of the intervertebral body fusion prosthetic material 1. It refers to the frame of non-porous structure that connects. Preferably, the body frame portion 15 is formed in a linear structure as shown in FIG. 5 to protect the corner portion of the intervertebral body fusion prosthesis 1, but has a non-porous structure that is disadvantageous to bone ingrowth. The solid part is prevented from being increased, and the flow of force is smoothly transmitted from the front side to the rear side during the propulsion process of the intervertebral body fusion prosthesis (1), and after positioning, the weight is withstanding the body load transmitted from the spine. The simplified fusion prosthetic material 1 is not damaged.

As shown in FIG. 5, the body frame part 15 includes a body fixing device 151.

The body fixing device 151 refers to a configuration protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis 1 . The body fixing device 151 allows the intervertebral body fusion prosthesis 1 to be easily propulsed, and when the intervertebral body fusion prosthesis 1 is positioned on a pre-planned position, By increasing the frictional force, the initial fixing force of the intervertebral body fusion prosthesis 1 can be secured. A plurality of body fixing devices 151 may be formed on the body frame part 15 .

The rim frame portion 17 refers to a frame having a non-porous structure formed along an inner circumferential surface of a through portion 50 to be described later. In the present invention, by configuring the rim frame portion 17 in the intervertebral body fusion prosthesis 1, the internal space 101 of the intervertebral body fusion prosthesis 1 through a through-hole 50 to be described later. The porous structure exposed in the process of filling the bone graft can be protected from being damaged by external force. Since the shape of the penetrating portion 50 to be described later is approximately circular, the shape of the rim frame portion 17 may be configured in an annular shape as shown in FIG. 5 .

Referring to FIG. 5 , the rim frame part 17 includes a first rim frame part 171 and a second rim frame part 173 .

The first rim frame portion 171 refers to a configuration formed along the inner circumferential surface of a first through portion 51 to be described later. As shown in FIG. 5 , the first rim frame part 171 may also have a ring shape. By constructing the first rim frame part 171, in the process of inserting the bone graft into the internal space 101 through the first through part 51 to be described later, it is formed in a porous structure and has relatively low strength. , It is possible to prevent the bone growth portion 30 around the first through portion 51 from being damaged, such as being broken or bent. As shown in FIG. 5, the first rim frame part 171 includes a first rim fixing device 1711.

The first rim fixing device 1711 refers to a configuration protruding obliquely from the first rim frame part 171 along the propulsion direction of the intervertebral body fusion prosthesis 1 . The first rim fixing device 1711 facilitates the propulsion of the intervertebral body fusion prosthetic material 1, but when the intervertebral body fusion prosthetic material 1 is positioned on a previously planned position, the neighboring intervertebral body fusion prosthetic material 1 is set. The fixing force between the vertebrae and the intervertebral body fusion prosthesis 1 is increased, preventing problems such as deviation of the intervertebral body fusion prosthesis 1 from its original position before bone fusion occurs. As shown in FIG. 5 , the first rim fixing device 1711 may be formed in plurality on the first rim frame part 171 .

The second rim frame part 173 is formed along the inner circumferential surface of the second through part 53 to be described later, and may preferably have a ring shape. If the upper side of the second bone growth portion 33 to be described later is coupled to the lower side of the first rim frame portion 171, the lower side of the second bone growth portion 33 to be described later is the second rim frame portion 173 It can be coupled to the upper side of. By constructing the second rim frame part 173, when a bone graft is inserted into the internal space 101 through the second through part 53 of the intervertebral body fusion prosthesis 1 to be described later, it is resistant to external force. As a result, it is possible to prevent damage to the porous portion. Referring to FIG. 5 , the second rim frame part 173 includes a second rim fixing device 1731 .

The second rim fixture 1731 is configured to protrude obliquely from the second rim frame part 173 along the propulsion direction of the intervertebral body fusion prosthesis 1, and is similar to the first rim fixture 1711. While enabling the propulsion of the intervertebral body fusion prosthesis 1, it is possible to secure an initial fixing force so that the positioning of the intervertebral body fusion prosthesis 1 does not move. The second rim fixing device 1731 may be formed in plurality on the second rim frame part 173, and may preferably be symmetrical with the first rim fixing device 1711.

The bone growth portion 30 refers to a configuration of a porous structure formed in a plurality of pores. As shown in FIG. 5, the bone growth portion 30 may be formed in a state in which a thin plate-shaped shell is unfolded or rolled, and the bone growth portion 30 is a shell type. By forming, it is possible to prevent an increase in the strength of the intervertebral body fusion prosthetic material 1 and to promote bone ingrowth by increasing the porosity so that rapid bone fusion can be achieved. Referring to FIG. 5, although the bone growth unit 30 is shown in a honeycomb structure (Cross Honeycomb), the porous structure of the bone growth unit 30 is not necessarily limited to this structure, and is not necessarily limited to this structure. Structures of other shapes may also be formed.

5 and 6, the bone growth portion 30 includes a first bone growth portion 31, a second bone growth portion 33, a third bone growth portion 35, and a fourth bone growth portion. It includes part 37.

The first bone growth part 31 is formed in a shell type to form an outer surface of the intervertebral body fusion prosthesis 1, and the inner space 101 formed by the frame part 10 ), so that a larger amount of bone graft can be filled in, and the bone graft inserted into the internal space 101 by the first bone growth part 31 is the intervertebral body It is prevented from escaping to the outside of the fusion retainer 1 and disappearing.

Preferably, the first bone growth portion 31 may be formed on the opening 103 formed by the frame portion 10 . More preferably, as shown in FIGS. 5 and 6 , the first bone growth portion 31 does not exceed the outermost profile of the opening 103 and does not exceed the innermost profile of the opening 103. It can be configured not to.

The first bone growth portion 31 does not exceed the outermost profile of the opening 103 formed by the frame portion 10, so that the first bone growth portion 31 has relatively low strength during the propulsion process. can be prevented from being damaged by external forces. In addition, the protection of the first bone growth portion 31 blocks the generation of fine particles (Porous Particle) due to damage to the first bone growth portion 31. Problems that can cause abnormal reactions such as inflammatory reactions by penetrating into blood vessels can also be prevented.

When the first bone growth portion 31 is configured not to exceed the innermost profile of the opening 103 formed by the frame portion 10, the inside into which a bone graft can be inserted. As the space 101 is sufficiently secured, the strength of the intervertebral body fusion prosthesis 1 is prevented from increasing.

The second bone growth part 33 is formed in a shell type and refers to a configuration that vertically connects the first rim frame part 171 and the second rim frame part 173. The rim frame portion 17 may be configured in a rim shape as shown in FIG. 5, so as to connect each of the rim frame portions 17 located on the upper and lower sides, the second bone growth portion 33 is As shown in Figure 5, it can be rolled into a cylindrical shape. By configuring the second bone growth portion 33, the strength of the intervertebral body fusion prosthetic material 1 is reinforced so that the intervertebral body fusion prosthetic material 1 can have resistance to vertical load.

Preferably, the size of the void formed by the second bone growth portion 33 is larger than the size of the void formed by the first bone growth portion 31, and inserted through the penetration portion 50 to be described later. A bone graft may be easily inserted into the space between the second bone growth part 33 and the first bone growth part 31 by passing through the second bone growth part 33. there is.

5 and 7, the second bone growth portion 33 has an outermost profile formed when the first rim frame portion 171 and the second rim frame portion 173 are connected vertically. It can be configured not to exceed. In addition, the second bone growth portion 33 may be configured not to exceed an innermost profile formed when the first rim frame portion 171 and the second rim frame portion 173 are connected vertically. The second bone growth part 33 is configured so that it does not exceed the outermost and innermost profiles formed by the first rim frame part 171 and the second rim frame part 173, so that bone graft It is possible to prevent the strength of the intervertebral body fusion prosthesis 1 from increasing while sufficiently securing the internal space 101 into which the intervertebral body fusion can be inserted.

As shown in FIG. 8, the third bone growth part 35 is formed in a shell type and refers to a configuration connecting the head frame part 11 and the second bone growth part 33. . In the process of pushing the intervertebral body fusion prosthetic material 1 into the space between the vertebrae, the third bone growth part 35 prevents the flow of external force due to friction with the surroundings from the head frame part 11. In addition to passing through the body frame part 15 and leading to the propulsion frame part 13 side, the third bone growth part 35 and the second bone growth part 33 in the head frame part 11, described later The intervertebral body fusion prosthesis 1 is driven by an external force in the process of pushing the intervertebral body fusion prosthesis 1 by passing through the fourth bone growth portion 37 to be sequentially connected to the propulsion frame 13 side. Make sure not to damage it. Preferably, the size of the void formed by the third bone growth part 35 is larger than the size of the void formed by the first bone growth part 31, so that the second bone in the inner space 101 A bone graft is allowed to pass through the gap of the third bone growth portion 35 that divides the space formed by the growth portion 33 and the first bone growth portion 31 .

As shown in FIG. 8, the fourth bone growth part 37 is formed in a shell type and refers to a configuration connecting the propulsion frame part 13 and the second bone growth part 33. . A bone graft inserted through the penetration part 50 to be described later passes through the second bone growth part 33, and the second bone growth part 33 and the first bone growth part 31 The fourth bone growth portion 37 formed on the space formed by the bone can also pass through, and can be evenly filled into the space formed by the second bone growth portion 33 and the first bone growth portion 31. In order to do so, it may be preferable that the size of the void formed by the fourth bone growth portion 37 is larger than the size of the void formed by the first bone growth portion 31 .

The through part 50 refers to a hole formed to penetrate from one side of the first bone growth part 31 to the other side and communicates with the inner space 101 of the frame part 10 . The through portion 50 allows a bone graft to be easily inserted into the inner space 101 of the intervertebral body fusion prosthesis 1 . The shape of the through portion 50 is not limited to any specific shape, but may preferably have a substantially circular shape. Referring back to FIG. 5 mentioned above, the through part 50 includes a first through part 51 and a second through part 53 .

The first through part 51 penetrates from one side to the other side of the first bone growth part 31 forming the upper side of the intervertebral body fusion prosthetic material 1 among the first bone growth parts 31. refers to the hole formed. A large amount of bone graft can be tightly packed into the inner space of the intervertebral body fusion prosthesis 1 through the first through-portion 51 . As described above, the first rim frame portion 171 may be formed on the inner circumferential surface of the first through portion 51 .

The second through part 53 penetrates from one side to the other side of the first bone growth part 31 forming the lower surface of the intervertebral body fusion prosthetic material 1 among the first bone growth parts 31. refers to the hole formed. Preferably, the second through part 53 is formed on a position opposite to the first through part 51 so that the first through part 51 and the second through part 53 face each other. can be configured. A large amount of bone graft is easily filled on the internal space 101 of the intervertebral body fusion prosthesis 1 through the first through part 51 and the second through part 53. be able to put In this process, the second rim frame portion 173 may be formed on the inner circumferential surface of the second through portion 53 to protect the porous portion.

9 is a perspective view showing an intervertebral body fusion prosthesis 1 having a shell-type porous structure according to another embodiment of the present invention. Referring to FIG. 9, the present invention intervertebral body fusion prosthetic material 1 In order to provide a difference in mechanical strength, the shape of the frame part 10 is maintained, but the size, thickness, shape, size of the strut of the bone growth part 30 in which a plurality of gaps are formed, the size of the gaps, etc. By changing, the intervertebral body fusion prosthetic material 1 can have different mechanical strengths. Through this, the customized intervertebral body fusion prosthetic material 1 suitable for the patient's bone strength can be easily manufactured. The manufacturing method of the intervertebral body fusion prosthesis 1 is not limited to any specific method, but may be preferably manufactured through an additive manufacturing method using a 3D printer.

10 is a use state diagram of the present invention. Referring to FIG. 10, the intervertebral body fusion prosthesis (1) of the present invention is inserted into the space between the vertebrae (B) from which the disc (D) has been removed, To achieve fusion between the vertebrae, as described above, a bone graft such as the patient's own bone is sufficiently inserted into the internal space 101 of the intervertebral body fusion prosthesis 1, Even if the intervertebral body fusion prosthetic material 1 into which the bone graft is inserted by the shell-type first bone growth portion 31 is impacted by a surgical instrument, the bone graft filled in (Bone Graft) can be prevented from escaping.

In addition, in the process of filling the inner space 101 with the bone graft, the rim frame part 17 is formed around the penetrating part 50, so that damage to the porous part with relatively low strength is prevented, The generation of fine particles (Porous Particle) can also be blocked.

Above all, as the strength of the intervertebral body fusion prosthesis 1 can have a strength similar to that of bone due to the bone growth portion 30 of a porous structure formed in a shell type, the strength is higher than that of bone Prevent bone subsidence caused by intervertebral body fusion implants.

Furthermore, since the body fixing device 151, the first rim fixing device 1711, and the second rim fixing device 1731 are formed on the upper and lower sides of the intervertebral body fusion prosthesis 1, the screw S and the rod R In addition to the fixing force by ), the initial fixing force of the intervertebral body fusion prosthetic material 1 itself can be increased, so that the intervertebral body fusion prosthetic material 1 deviates from its original position before complete fusion is achieved. can solve

The above detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and describe preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed in this specification, within the scope equivalent to the written disclosure and / or within the scope of skill or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in the specific application field and use of the present invention are also possible. Therefore, the above detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to cover other embodiments as well.

1: intervertebral body fusion prosthesis having a shell-type porous structure
10: frame part
11: head frame part
13: propulsion frame
15: body frame part
151: body fixation
17: rim frame part
171: first rim frame part
1711: first rim fixation
173: second rim frame part
1731: Second rim fixation
30: bone growth ledger
31: first bone growth ledger
33: second bone growth ledger
35: third bone growth ledger
37: fourth bone growth ledger
50: through part
51: first penetration part
53: second penetration part

Claims (19)

A frame portion of a non-porous structure forming a skeleton of the intervertebral body fusion prosthetic material;
It includes a bone growth portion of a porous structure formed in a plurality of pores,
The bone growth portion is formed in a shell type and includes a first bone growth portion forming an outer surface of the intervertebral body fusion prosthesis, characterized in that, the intervertebral body fusion prosthesis having a shell-type porous structure. According to claim 1,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the frame part forms an inner space, which is an empty inner space, and an opening, which is an open surface communicating the inner space with the outside of the intervertebral body fusion prosthesis. . According to claim 2,
The first bone growth portion is characterized in that formed on the opening, the intervertebral body fusion prosthesis having a shell-type porous structure. According to claim 3,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the first bone growth portion does not exceed the outermost profile of the opening. According to claim 3,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the first bone growth portion does not exceed the innermost profile of the opening. According to claim 2,
The intervertebral body fusion beam having a shell-type porous structure, characterized in that the intervertebral body fusion prosthesis further comprises a penetrating portion, which is a hole formed to penetrate from one side of the first bone growth portion to the other side and communicates with the inner space. Brother. According to claim 6,
The through part includes a first through part formed to pass through the first bone growth part forming the upper side surface and a second through part formed to pass through the first bone growth part formed into the lower surface of the shell. An intervertebral body fusion prosthesis having a porous structure of the type. According to claim 7,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the first through-portion and the second through-portion are formed on opposite sides of each other. According to claim 8,
The frame part includes a first rim frame part formed along the inner circumferential surface of the first through part and a second rim frame part formed along the inner circumferential surface of the second through part, characterized in that the intervertebral body having a shell-type porous structure. fusion implant. According to claim 9,
The bone growth portion is formed in a shell type and includes a second bone growth portion vertically connecting the first rim frame portion and the second rim frame portion, and having a shell-type porous structure. Simplified fusion prosthesis. According to claim 10,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the second bone growth portion has a larger gap than the first bone growth portion. According to claim 10,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the second bone growth part does not exceed the outermost profile formed by the first rim frame part and the second rim frame part. According to claim 10,
The second bone growth portion does not exceed the innermost profile formed by the first rim frame portion and the second rim frame portion. According to claim 10,
The frame part includes a head frame part formed on the front side of the intervertebral body fusion prosthesis,
The bone growth part is formed in a shell type and includes a third bone growth part connecting the head frame part and the second bone growth part, characterized in that the intervertebral body fusion prosthesis having a shell-type porous structure . In paragraph 14,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the third bone growth portion has a larger gap than the first bone growth portion. According to claim 10,
The frame part includes a propulsion frame part formed on the rear side of the intervertebral body fusion prosthesis,
The bone growth part is formed in a shell type and includes a fourth bone growth part connecting the propulsion frame part and the second bone growth part, characterized in that the intervertebral body fusion prosthesis having a shell-type porous structure . In clause 16,
The fourth bone growth portion is characterized in that the size of the gap is larger than the first bone growth portion, the intervertebral body fusion prosthesis having a shell-type porous structure. According to claim 1,
The frame unit includes a body frame unit connecting a head frame unit formed on the front side of the intervertebral body fusion prosthesis and a propulsion frame unit formed on the rear side of the intervertebral body fusion prosthesis,
The intervertebral body fusion prosthesis having a shell-type porous structure, characterized in that the body frame part includes a body fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis. According to claim 9,
The first rim frame part includes a first rim fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis,
The second rim frame part includes a second rim fixing device protruding obliquely along the propulsion direction of the intervertebral body fusion prosthesis, characterized in that, the intervertebral body fusion prosthesis having a shell-type porous structure.

Images