KR101370424B1 - Spinal composite implant - Google Patents

Abstract

The present invention includes a cage formed of a resin material having a hollow portion, a first opening portion communicating the hollow portion with the outside, and a second opening portion facing the first opening portion and communicating the hollow portion with the outside; And a metal layer attached to an outer surface of the cage and formed of a porous metal material.

Description

Spinal Complex Implants {SPINAL COMPOSITE IMPLANT}

The present invention relates to a spinal implant for treating spinal diseases by fusion surgery.

With the transition to a aging society, the number of patients with spinal diseases such as intervertebral stenosis, intervertebral disc herniation, and hip joint hypertrophy is increasing rapidly.

Spinal implants (spinal implants) are used in the long-term fusion surgery of such degenerative spine (including lumbar spine, cervical spine) disease, also known as the spinal fusion implant (spinal cage).

Spinal implants are medical devices in the form of cages that are implanted between bones or implantable bones to treat structural abnormalities in the spine. The implanted spinal implant restores the height of the intervertebral body and the curvature of the spine and structurally supports the vertebral body.

There are various types of spinal implants depending on the design, the method of treatment, etc., and the development of a shape for restoring the biomechanical stability of the spine is possible.

Resin is mainly used as a material of a spinal implant. By the way, while the resin is good elasticity, structural strength or bone union at the surface may be a problem.

An object of the present invention is to provide a composite implant for the spine, which is good in elasticity and easy to union, while also improving the structural stability, and also to determine whether the union is well after the procedure in the X-ray examination.

The composite implant for a spine related to an embodiment of the present invention for realizing the above object includes a hollow portion, a first opening portion for communicating the hollow portion with the outside, and the first opening portion facing the hollow portion. A cage formed of a resin material, the cage having a second open portion communicating with the outside; And a metal layer attached to an outer surface of the cage and formed of a porous metal material.

Here, the cage, the first opening portion for communicating the hollow portion with the outside; And a second opening positioned to face the first opening and communicating the hollow portion with the outside.

Here, the metal layer may include a cover part covering the second opening part to close the second opening part.

Here, a through hole may be formed in the central area corresponding to the second opening of the cover part.

Here, the metal layer may include a ring portion formed in a ring shape surrounding the first opening portion or the second opening portion.

The cage may be formed of a polyetheretherketone (PEEK), and the metal layer may be formed of a titanium alloy, nitinol, or a cobalt-chromium alloy.

Here, the porosity of the metal layer may be 30% to 90%.

Here, the metal layer may have a thickness of about 100 μm to about 1 mm.

Here, the metal layer may be thermocompressed to the cage.

Here, the outer surface of the metal layer may be SLA (Sand-blasted, Large grit, Acid etched).

Here, the first opening portion and the second opening portion may be formed to have a track-shaped cross section, and a side surface adjacent to any one of both sides of the track-shaped cross section of the cage may be formed as a curved surface.

According to the composite implant for the spine according to the present invention configured as described above, the elasticity is good and the bone union is easy and structural stability can be increased. This assists in the rapid normalization of the implant procedure and allows the implant to remain stable. In addition, during the X-ray examination after the procedure it is possible to check whether the union is well in the implant through the resin cage.

1 is an exploded perspective view of a composite implant for the spine 100 according to an embodiment of the present invention.
FIG. 2 is an assembled perspective view of the composite implant 100 for the spine as viewed from the bottom side.
3 is a perspective view of a composite implant 200 for the spine in accordance with another embodiment of the present invention.
4 is a perspective view of a composite implant 300 for the spine according to another embodiment of the present invention.
5 is a photograph of a surface treatment that may be applied to the metal layer 130 of FIG. 1.

Hereinafter, with reference to the accompanying drawings for the composite implant for the spine according to a preferred embodiment of the present invention will be described in detail. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is an exploded perspective view of the composite implant for the spine 100 according to an embodiment of the present invention, Figure 2 is an assembly perspective view as viewed from the lower side of the composite implant for spine 1 of FIG.

Referring to this figure, the composite implant for the spine 100 may include a cage 110 and a metal layer 130.

The cage 110 may have a shape similar to a rectangular parallelepiped as a resin material. The hollow part 111 is formed in the center of the cage 110. The hollow part 111 may communicate with the outside through the first opening part 112 and the second opening part 113. In this case, the first opening part 112 and the second opening part 113 may be disposed to face each other. In this case, the center of the cage 110 is opened to penetrate along one direction along the first opening 112, the hollow 111, and the second opening 113. In the present embodiment, the first opening 112, the second opening 113, and the hollow 111 have a track-shaped cross section.

The cage 110 has an upper surface 115, a side surface 116, and a lower surface (the opposite surface of the upper surface 115). Here, the side 116 is used to collectively refer to approximately four sides. One or more openings 117 may be formed in the side surface 116. Through the opening 117, the hollow part 111 is also in communication with the outside in the side surface 116 direction.

The front part 118 and the rear part 119 may be defined corresponding to both sides of the said track-shaped cross section among the side surfaces 116, respectively. The front portion 118 is formed to form a curved surface. This has the advantage of reducing the force for insertion when inserting the composite implant 100 for the spine. On the contrary, the rear portion 119 may be flat for the convenience of processing. The tool hole 120 is formed at the center of the rear part 119. Tool hole 120 is a hole to which a tool for pushing the complex implant 100 for the spine is coupled. A thread is formed on the inner surface of the tool hole 120 to be coupled to the thread of the tool.

The metal layer 130 is a porous metal layer and is attached to the outer surface of the cage 110. In this embodiment, the metal layer 130 is attached to the top surface 115 and the bottom surface of the cage 110.

The metal layer 130 may include a cover part 131 and a ring part 135 according to a shape.

The cover 131 is a plate that is entirely blocked, and is attached to the lower surface of the cage 110 to close the second opening 113. The cover part 131 may help to prevent the bone graft material from being separated from the hollow part 111 during the procedure of placing the bone graft material into the hollow part 111.

On the contrary, the ring part 135 has a shape in which the center is opened to surround the first opening part 112 and has a ring-like shape as a whole. The open center portion of the ring portion 135 may have a track-shaped cross section corresponding to the shape of the first opening portion 112. Thereby, even if the ring portion 135 is attached to the upper surface 115, the open area of the first opening portion 112 may not be affected. Alternatively, the open area in the center of the ring portion 135 may be formed somewhat smaller than the open area of the first opening 112.

By the shape of the cover portion 131 and the ring portion 135, after the procedure of the implant 100, the bone of the spine through the ring portion 135 and the first opening 112, and the opening 117 It flows into the hollow part 111.

The porosity of the metal layer 130 may range from 30% to 90%. The metal layer 130 has pores in order to increase the surface area so that the union effect is maximized on the surface of the metal layer 130. The bone union effect is a level to increase the completeness of the procedure if the porosity is more than 30%, if the 90% exceeds the self-stiffness of the metal layer 130 is insufficient.

The thickness of the metal layer 130 is set to 100 μm to 1 mm. When the thickness of the metal layer 130 is less than 100 μm, it is difficult to exert the biocompatibility and bone union function of the metal layer 130, and when the thickness of the metal layer 130 exceeds 1 mm, it becomes a factor that restricts the elasticity of the composite implant 100 for the spine. In addition, the load on the spine may cause a problem that the adhesion to the cage 110 is also dropped.

In the above description, the cage 110 may be formed of a peak (PEEK: Polyetheretherketone), and the metal layer 130 may be formed of a titanium alloy, nitinol, or cobalt-chromium alloy (Co-Cr alloy). have. Cage 110 of the peak material is good elasticity and transmits X-rays. The metal layer 130, such as a titanium alloy material, has good rigidity and impervious to X-rays, but the interference phenomenon is not large due to pores. Thereby, the composite implant for the spine 100 has elasticity and rigidity.

In addition, after the procedure in the X-ray examination through the cage 110 can be confirmed whether the bone union for the complex implant 100 for the spine is well made. The metal layer 130 may act as a marker by X-ray impermeability during X-ray inspection. In other words, by determining the position of the edge portion of the metal layer 130, it is possible to determine whether the spinal complex implant 100 is located at the position where the procedure is performed.

Since the metal layer 130 has a porosity, the surface is rough so that the union is well achieved, thereby preventing the implant 100 from falling out after the procedure. This eliminates the need for additional means such as forming teeth on the outer surface of the cage 110 to prevent retraction of the implant 100 when the metal layer 130 is not attached to the outer surface of the cage 110. do.

In order to attach the metal layer 130 to the cage 110, a thermocompression method may be used. Specifically, after heating and softening the cage 110 made of a resin material, the metal layer 130 may be pressed against the outer surface of the cage 110. According to him, the outer surface side portion of the body of the cage 110 is melted into the pores of the metal layer 130 to form the thermocompression unit (110b). The inner part of the body of the cage 110 maintains its shape as the base portion 110a, and supports the thermocompression-bonding portion 110b. By this thermocompression, the strength of the mechanical coupling between the cage 110 and the metal layer 130 is increased, thereby reducing the possibility of the metal layer 130 falling off the cage 110.

Next, implants having other types of metal layers will be described with reference to FIGS. 3 and 4.

3 is a perspective view of a composite implant 200 for the spine in accordance with another embodiment of the present invention.

Referring to the figure, the composite implant for the spine 200 is generally the same as the implant 100 of the previous embodiment, but one or more through-holes 232 are formed in the cover portion 231 of the metal layer 230 There is a difference.

As the through hole 232 is formed, the hollow part 211 is not completely blocked at the second opening part 213, but communicates with the outside through the through hole 232. The body part 233 in which the through hole 232 is not formed in the cover part 231 partially closes the second opening part 213.

The cover portion 231 has a body portion 233, to help prevent bone graft material from being separated from the hollow portion 211 in the process of putting the bone graft (hollow graft) in the hollow portion 211, the procedure Gives. In addition, the bone around the implant 200 may be introduced into the hollow part 211 through the through-hole 232 after the implant 200.

Next, Figure 4 is a perspective view of the composite implant 300 for the spine according to another embodiment of the present invention.

Referring to the figure, the composite implant 300 for the spine is generally the same as the implant 100 of the previous embodiment, but the difference is that the metal layer 330 all have the shape of the ring portion (335a, 335b) have.

According to this configuration, the metal layer 330 does not help to prevent the bone graft material from being separated from the hollow portion 311 during the procedure of putting the bone graft material into the hollow portion 311. However, after the implant 300, the bone around the implant 300 is not constrained by the metal layer 330, but freely through the first opening 312 and the second opening 313 through the hollow 311. Can be introduced into. This provides an advantage of facilitating mid- and long-term settling after the implant 300.

Finally, the surface treatment of the metal layers 130, 230, and 330 will be described with reference to FIG. 5.

5 is a photograph of a surface treatment that may be applied to the metal layer 130 of FIG. 1. In the drawing, only the metal layer 130 is referred to for convenience, but it will be understood by those skilled in the art that the present invention may be applied to other metal layers 230 and 330.

Referring to this figure, the metal layer 130 may be treated like the surface illustrated in this figure. In this figure, the surface treated with SLA (Sand-blasted, Large grit, Acid etched) is shown.

SL is a method in which particles such as aluminum oxide (Al ₂ O ₃ ) are sprinkled on the surface of a metal to be treated to form large particles, followed by acid treatment of the metal with hydrochloric acid, sulfuric acid, and the like. By this acid treatment, small particles are further formed. In other words, physical blasting and chemical acid treatment are combined so that the surface of the metal has both large and small rough portions at the same time.

Such surface treatment such as SL is possible by the metal layer 130 rather than the cage 110 itself to form the outer surface of the composite implant 100 for the spine. The metal layer 130 may be subjected to other surface treatment in addition to SL to improve surface roughness.

Such a composite implant for the spine is not limited to the configuration and manner of operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100,200,300: Composite implant for spine 110,210,310: Cage
111,211,311: Hollow part 112,212,312: First opening part
113,213,313: second openings 130,230,330: metal layer
131,231: cover portion 135,235,335a, 335b: ring portion

Claims (11)

A cage formed of a resin material having a hollow portion, a first opening portion communicating the hollow portion with the outside, and a second opening portion facing the first opening portion and communicating the hollow portion with the outside; And
Attached to the outer surface of the cage, comprising a metal layer formed of a porous metal material, composite implant for the spine.
delete The method of claim 1,
And the metal layer comprises a cover portion covering the second opening and closing the second opening.
The method of claim 3,
The implant of claim 1, wherein a through hole is formed in a central region corresponding to the second opening of the cover portion.
The method of claim 1,
The metal layer, the composite implant for the spine comprising a ring portion formed in the shape of a ring surrounding the first opening or the second opening.
The method of claim 1,
The cage is formed into a peak (PEEK: Polyetheretherketone),
The metal layer is a composite implant for the spine, formed of a titanium alloy (Nitinol) or cobalt-chromium alloy (Co-Cr alloy).
The method according to claim 6,
The porosity of the metal layer is 30% to 90%, the composite implant for the spine.
The method according to claim 6,
The composite implant for the spine, wherein the metal layer has a thickness of 100 μm to 1 mm.
The method of claim 1,
And the metal layer is thermocompressed to the cage.
The method of claim 1,
The outer surface of the metal layer is SLA (Sand: Sand-blasted, Large grit, Acid etched) treated, a composite implant for the spine.
The method of claim 1,
The first opening and the second opening is formed to have a track-shaped cross section,
The side of the cage adjacent to any one of both sides of the track-shaped cross-section is a composite implant for the spine.

Images