KR100847895B1 - Device for performing osteosynthesis - Google Patents

Abstract

The device for bone bonding is formed to accommodate a lower surface (2) capable of supporting the bone, an upper surface (3), and a bushing (10) for adjusting the angle in multiple axes for the bone screw (20). It comprises a bone plate (1) provided with at least one through hole (4) communicating the upper surface (3) and the lower surface (2). The through hole 4 has a central axis 5. The apparatus for bone bonding includes a bushing 10 having an inner diameter 11 having a longitudinal axis 12 and having an outer surface 17 formed in contact with the through hole 4. It is configured to include.

The bushing 10 is formed radially compressible and radially tensionable. The cross section 6 of the through hole 4 is formed in a non-circular shape on a line extending perpendicular to the central axis 5.

The cross section 16 of the linear bushing 10 extending orthogonally to the longitudinal axis 12 is formed in a shape substantially corresponding to the shape of the cross section 6 of the through hole 4 of the bone plate 1. have. The bushing 10 formed in the through hole 4 is rotatably stabilized along the longitudinal axis 12 of the bushing 10. In addition, along the position of the bushing 10 according to the bone plate (1) is present to be adjustable in the through hole (4).

Description

Device for performing osteosynthesis

The present invention relates to a device for bone bonding, and more particularly to a device for bone bonding consisting of a bone plate, bone screws and bushings.

The present invention relates to a device for bone bonding as can be specified in claim 1.

The device of this type is formed in multiple axes, formed of a strong material, and tightened and installed by components such as pedicle screws and pedicle hooks that can be specifically applied to portions of the spinal column. However, the elements are also generally applied by plating. The area of application is used in combination with an external fixation member and an intervertebral implant.

An apparatus of this type is already disclosed by US 6235033. In the publication, the inner diameter of the screw head and bone plate is applied together by an annular bushing which is compressible, tensionable and angled by a slot so that the tightening of the screw in the bone plate is improved. However, the bushing used in the known device is of circular shape for rotation with the screw tightened in the bushing. Thus, the bushing is not fixed to the plate. The bushing is completely rotated in the plate cavity. Therefore, the wrong direction is pointing upwards (the inner cone is tapered in the wrong direction).

The discussion of the state of the art described above is not merely intended to explain the background of the invention. And it does not mean that the above mentioned technology is actually published or published to the public at the time the application is made or at the time of priority.

The present invention is directed to a solution to this. Accordingly, it is an object of the present invention to develop a device for bone bonding in which the bone screw moves in multiple axes and is multi-stable and securely coupled along the bone plate without requiring any additional components.

According to the present invention, the object is achieved by the device shown in claim 1.

Next, the word "non-circular" should be understood to mean any cross-section away from a complete circle. That is, the non-circular shape is described as the shape of the prism or the cross section of the ellipse.

An advantage with the present invention is that when the bone screw is tightened in the bushing, the bushing no longer rotates about the axis of the bushing. The rotation of the bushing actually causes the relative movement between the bushing and the screw to no longer occur. Thus, the bushing is not detached and consequently the screw is not secured. Another advantage is that, unlike the device according to US 6235033, no additional fastening screws are required.

In one embodiment, the cross section of the through hole formed in the apparatus for bone bonding, preferably implemented in the shape of a bone plate, is formed in a polygon, preferably in a hexagon. Therefore, the through hole has the shape of a prism and is preferably formed as a hexagonal prism. In the embodiment formed in the hexagon, the bone screw is moved along three sides at the same time through the hexagonal through-holes. Thus, the screw can be fixed and adjusted at any desired angle. The angle is only determined by the thickness of the plate and the contact of the bushing to the reduced cross section. It is also possible to use the bone plate having several through holes.

In another embodiment, the diameter of the inner diameter of the bushing is formed to taper in one direction. The inner diameter is preferably formed in a cone shape. In this form, the bushings are separated by corresponding mating cones. However, of course, the inner diameter formed in the bushing may be implemented in a circular cylinder shape.

Preferably, the internal thread is formed in the inner diameter of the bushing. This makes it possible to fix the bushing.

On a line extending at right angles to the central axis, the cross section of the through hole formed in the device for bone bonding, preferably the cross section of the through hole made of a bone plate, may also be elliptical.

In another embodiment, the cross-section of the through hole is formed by combining two non-circular lines with two incomplete semicircles, respectively. In this case, two bushings are formed on an outer surface of the bushing so that the bushing can be inserted into a groove formed by a non-circular line of the through hole.

For radial compression and radial tension, the bushing may have a through slot formed therein. Preferably the slot is formed parallel to the longitudinal axis of the bushing. In another embodiment the bushing is formed with a plurality of slots unperforated in the bushing and preferably parallel to the longitudinal axis.

As for the surface of the said bushing, Preferably, the outer side surface is appropriately formed roughly. In other words, the rough shape of the outer surface is formed by grit blasting. The through hole formed in the bone plate is roughly formed to correspond to the surface of the bushing. The rough shape of the through hole is also formed by grit blasting. However, the surface of the bushing is preferably provided with an outer ridge in which the outer surface is formed in a macro structure. An inner ridge formed in a macro structure is also formed in the through hole. The advantage of this shape is that the coupling between the bushing and the bone plate as described above is improved.

Another embodiment is preferably formed such that the through hole formed in the bone bonding apparatus implemented with the bone plate is tapered toward the lower surface of the bone bonding apparatus. Preferably, the same applies to the upper surface of the apparatus for bone bonding. Thus, a reduced cross section is formed in the bone bonding device such that the bushing does not escape or extrude from the bone bonding device. Further, the reduced cross section of the through hole and the compressibility of the bushing are appropriately selected so that the bushing compressed in the through hole can be inserted.

The shape of the outer surface of the bushing is suitably formed in the shape of a convex lens, preferably in the shape of a cylinder.

Preferably, the surface of the through hole and the bushing and the outer surface of the bushing in the apparatus for bone bonding are made of at least different materials. Preferably, the strength of the material is configured differently. For example, the bushing may be made of a plastic material that can be bonded to a living body, and the bone bonding device (ie, a bone plate) may be made of a metal material that can be bonded to a living body. However, the bushing may be made of metal material and the apparatus for bone bonding may be made of plastic material. Preferably, the plastic material will consist of reinforced plastic material. The different strength materials result in plastic deformation of the surfaces resulting in better bonding of the bone bonding device and the bushing.

The height of the bushing measured along the longitudinal axis of the bushing should be smaller than the height of the through hole formed in the bone plate measured along the central axis of the bone plate. The height of the bushing is suitably present between 40 and 85% of the height of the through hole, and preferably between 45 and 65% of the height of the through hole.

The bone screw, preferably inserted into the bushing, has a conical screw head. The screw head is formed with an external thread. The advantage of this shape is that the bushing can be detached or fixed simply.

Next, the present invention and the improvements of the present invention will be described in detail based on some of the embodiments shown in the drawings. All of the above embodiments apply to all bone bonding devices implemented in the shape of a bone plate. Similar applications include pedicle screws, pedicle hooks, lateral fixation members, and intervertebral implants.

1 is a perspective view of a device for bone bonding carried out in the shape of a bone plate.

2 is a cross-sectional view of the bone plate according to FIG. 1 with a bushing inserted into the device.

3 is a perspective view of a bushing for use with the device for bone bonding;

Figure 4 shows a cross section of the bushing according to figure 3;

5 is a perspective view of a device for bone bonding and a bushing used therein.

6 is a cross-sectional view of another example of a bone plate.

7 is a perspective view of the bushing used in the device for bone bonding in engagement with the bone plate according to FIG. 6.

8 is a longitudinal sectional view of the bone screw used with the device for bone bonding.

The device for bone bonding shown in Figures 1 to 4 is composed of a bone plate (1). The bone plate 1 penetrates the lower surface 2, the upper surface 3, and the upper surface 2 and the lower surface 3 which are formed to support the bone, and is shown in FIG. 8. It is composed of a through hole (4) formed to accommodate the bushing 10 that can be adjusted to various angles (multi-axis). The through hole 4 includes a central axis 5. The bushing 10 that can be inserted into the through hole 4 shown in FIG. 3 includes an inner diameter 11 that can receive the bone screw 20 and includes a longitudinal axis 12. And the outer surface 17 of the bushing 10 is formed in contact with the through hole (4).

The bushing 10 is formed with a slot 13 through which it is radially compressible and radially tensionable. The through hole 4 of the bone plate 1 has a cross section 9 which is reduced toward the lower surface 2 and the upper surface 3. The reduced cross section 9 is intended to prevent the bushing 10 from being separated or extruded from the through hole 4. Preferably, the compressed cross-section 9 of the through hole 4 and the compressibility of the bushing 10 are appropriately selected so that the compressed bushing 10 is inserted into the through hole 4.

As shown in FIG. 3, the surface of the bushing 10 is formed with an outer ridge 18 formed in a macro structure on the outer surface of the bushing 10. Correspondingly, an inner ridge 19 formed in a macro structure is formed in the through hole 4 of the bone plate 1 as shown in FIG. 2.

As shown in FIG. 4, the end face 6 of the through hole 4 on an extension line orthogonal to the central axis 5 is formed in a substantially hexagonal shape. In other words, the cross section 6 of the through hole 4 is not circular. The end face 16 of the bushing 10 on an extension line orthogonal to the longitudinal axis 12 is essentially formed in a shape corresponding to the end face 6 of the through hole 4 of the bone plate 1. Thus, the bushing 10 provided in the through hole 4 is rotatably stabilized along its longitudinal axis 12. In addition, the bushing 10 with respect to the bone plate (1) is able to adjust the angular position in the through hole (4).

As shown in FIG. 2, the diameter of the inner diameter 11 is tapered toward the lower surface 2 of the bone plate 1. Therefore, the inner diameter 11 is formed in a conical shape. In addition, an inner screw thread 15 is formed in the inner diameter 11.

5 shows another embodiment of the bushing 10 with a plurality of non-penetrating slots 14 extending parallel to the longitudinal axis 12. This shows that the bushing 10 is radially compressible and radially stretchable even without a through slot.

6 and 7 show another embodiment of another bushing 10 and bone plate 1. The cross section 6 of the through hole 4 in the bone plate 1 is formed by connecting two non-circular lines 8 to two incomplete semicircles 7. Correspondingly, the bushing shown in Fig. 7 is formed in the shape of a ring. The outer surface 17 of the bushing is formed into a spherical surface and semicircular protrusions 26 are formed on both sides thereof to oppose each other. The protrusion 26 is inserted into a groove formed by the non-circular line 8 in the through hole 4 of the bone plate 1. The through hole 4 is also formed in a spherical surface. When the bushing 10 is inserted into the bone plate, the bushing 10 rotates the projections 26 on both sides about the axis and rotates perpendicularly to the rotation axis. Thus, the bushing can move in all directions and can adjust the movement of the bushing regardless of the movement in the face of the bone plate.

The bushing 10 is formed to accommodate the bone screw 20 shown in FIG. The bone screw 20 has a screw shaft 21 for fixing the bone screw 20 in the bone, a central shaft 23, a screw head for insertion into the inner diameter 11 of the bushing 10. It includes (22). The screw head 22 is formed to essentially correspond to the shape of the inner diameter (11). The cross section of the screw head 22 on an extension line orthogonal to the central axis 23 is approximately tapered toward the screw shaft 21. Thus, the screw head 22 forms a cone. The screw head 22 is formed with an external thread 24. The outer thread 24 is engaged with the inner thread 15 of the bushing 15. In addition, the screw head 22 is formed in the shape of a hexagonal socket 15 that can accommodate an Allen key (not shown).

Next, an example of use of the bone bonding apparatus will be described briefly.

In the device the bushing 10 is temporarily fastened to the bone plate 1 or the jaw. Thus, it does not need to be inserted by a doctor. The bone plate 1 to which the bushing 10 is temporarily fastened is applied to the bone. This can be done either before or after conquering the body of the spine or other bone fragments.

Three possible methods for locating the bone screws are described below.

a) drilling, tapping, screwing

b) drilling, screwing (with tapping screws) or

c) screwing (using drilled and tapped screws)

It is also possible to use aiming devices or drill bushings. Of course, using a fixed aiming device is not appropriate. It may be as if that counterbalances the advantages of a screw that can adjust the angle. Nevertheless, such a aiming device is also preferably operated when the adjustment range is limited. Drill bushings are needed when screws that do not have the ability to drill themselves are used, or where a hole must be formed first before inserting the screws. In this case the drill bushing is used to prevent thin film wounds.

There are basically two ways to position the bone screw.

A) If bone reduction takes place first before applying the bone plate, the screw will have to be tightened immediately. And,

B) If bone reduction occurs after applying the bone plate, the screw is first inserted to secure the plate over the bone. The last bone reduction or correction is then made. And, the screw is inserted at various angles to be fixed to the bone plate.

The present invention relates to a device for bone joining consisting of a bone plate, bone screws and bushings, the bone screw does not require any additional components, the advantage of being able to move in multiple axes and plurally and stably coupled according to the bone plate There is this.

Claims (34)

A) through-hole 4 for accommodating an angled bushing 10 for the bone screw 20 and having a central axis 5, and B) an inner diameter 11 formed to accommodate the bone screw 20 and including a longitudinal axis 12, and an outer surface 17 formed to contact the inner side of the through hole 4, and the through hole ( In the device for bone bonding comprising a bushing 10 that can be inserted into 4), C) the bushing 10 is embodied radially compressible and radially tensionable, D) the cross section 6 on the extension line orthogonal to the central axis 5 is formed in a non-circular shape, E) the cross section of the bushing 10 on an extension line orthogonal to the longitudinal axis 12 is essentially formed in a shape corresponding to the cross section 6 of the through hole 4, F) The bushing 10 inserted into the through hole 4 is tightened against a rotational movement along the longitudinal axis 12 of the bushing 10 but the angular position of the bushing according to the through hole 4 is adjusted. Device for bone bonding, characterized in that the adjustable. The method of claim 1, A device for bone bonding, characterized in that the cross section (6) of the through hole (4) forms a polygon. The method according to claim 1 or 2, Bone joining device, characterized in that the through hole (4) forms the shape of a prism. The method according to claim 1 or 2, The through hole (4) and the bushing (10) is a device for bone bonding, characterized in that formed as a cog wheel. The method according to claim 1 or 2, Bone joining device, characterized in that the diameter of the inner diameter (11) of the bushing (10) is formed to taper in any one direction. The method according to claim 1 or 2, Bone joining device, characterized in that the inner diameter (11) of the bushing (10) is formed in a circular cylinder shape. The method according to claim 1 or 2, Bone joining device, characterized in that the inner thread (15) is formed in the inner diameter (11) of the bushing (10). The method according to claim 1 or 2, A device for bone bonding, characterized in that the cross section (6) of the through hole (4) is formed in the shape of an ellipse. The method according to claim 1 or 2, The end face (6) of the through hole (4) is bone bonding device, characterized in that formed by two incomplete semicircles (7) connected by a non-circular line (8). The method of claim 1, The bushing (10) device for bone bonding, characterized in that to form a through slot (13). The method of claim 10, Device for bone bonding, characterized in that the slot (13) extends parallel to the longitudinal axis (12). The method of claim 10, The bushing (10) device for bone bonding, characterized in that a plurality of non-penetrating slots (14) are formed. The method according to claim 1 or 2, Device for bone bonding, characterized in that the surface of the bushing (10) is roughened. The method according to claim 1 or 2, The surface of the bushing (10) is a bone bonding device, characterized in that the coating by a material stronger than the material of the bushing (10). The method according to claim 1 or 2, The surface of the bushing (10) is a bone bonding device, characterized in that formed in a macro structure. The method according to claim 1 or 2, The through hole (4) is a device for bone bonding, characterized in that the rough formed. The method according to claim 1 or 2, Device for bone bonding, characterized in that the through hole 4 is coated by a material stronger than the device for bone bonding. The method according to claim 1 or 2, The through hole (4) is a device for bone bonding, characterized in that formed in a macro structure. The method of claim 1, The through hole 4 is characterized in that the bone joint is characterized in that toward the lower surface 2, the bushing 10 is formed with a reduced end 9 to prevent the bushing 10 from being separated or extruded from the through hole 4. Device. The method of claim 10 or 19, The reduced end 9 of the through hole 4 and the compressibility of the bushing 10 are each appropriately selected and applied such that the compressed bushing 10 is insertable into the through hole 4. Device for bone bonding. The method according to claim 1 or 2, The outer surface (17) of the bushing (10) is a bone bonding device, characterized in that formed in a convex lens shape. The method according to claim 1 or 2, The inner surface of the through hole (4) is formed in a concave lens shape, the outer surface (17) of the bushing (10) is bone bonding device characterized in that formed in the shape of a prism. The method according to claim 1 or 2, The bone bonding device of the bone bonding device, characterized in that at least one of the surface of the through hole (4), the bushing (10), the outer surface (17) of the bushing is formed of a different material. The method according to claim 1 or 2, The bone bonding device is formed of a plastic material and the bushing (10) is a bone bonding device, characterized in that formed of a metallic material. The method according to claim 1 or 2, The height of the bushing 10 measured in the longitudinal axis 12 direction of the bushing 10 is smaller than the height of the through hole 4 measured in the direction of the central axis 5 of the through hole 4. Device for bone bonding. The method of claim 25, Device for bone bonding, characterized in that the height of the bushing (10) is between 40 to 80% of the height of the through hole (4). The method according to claim 1 or 2, A bone screw 20 having a screw shaft 21 to be fixed in the bone, a central shaft 23, and a screw head 22 formed to be inserted into the inner diameter 11 of the bushing 10; Screw head (22) is characterized in that formed essentially corresponding to the shape of the bushing (10) inner diameter (11). The method of claim 27, A device for bone bonding, characterized in that the cross section of the screw head (22) linearly extending perpendicular to the central axis (23) is tapered towards the screw shaft (21). The method of claim 27, The screw head 22 is a bone bonding device, characterized in that the outer thread 24 is formed. The method according to claim 1 or 2, The apparatus for bone bonding includes a lower surface 2, an upper surface 3, and at least one through hole 4 passing through the upper surface 3 and the lower surface 2 so as to be supported against the bone. Device for bone bonding, characterized in that the bone plate (1) comprising. The method according to claim 1 or 2, The bone bonding device is a bone bonding device, characterized in that the pedicle screw or pedicle hook. The method according to claim 1 or 2, The device for bone bonding is a device for bone bonding, characterized in that the external fixing member. The method according to claim 1 or 2, The device for bone bonding is a device for bone bonding, characterized in that the implant between the spine. The method of claim 1, The through-hole 4 is characterized in that the bone joint is characterized in that toward the top surface 3, the end portion 9 is formed to reduce the bushing 10 is separated or extruded from the through-hole 4 Device.

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