KR20200080622A - Bone anchor assemblies for Multi-axial coupling - Google Patents

Abstract

The present invention relates to a bone anchor assembly capable of fixing an anchor screw by changing the bone insertion axial direction of the anchor screw variously in accordance with a surgery portion and situation. According to the present invention, the bone anchor assembly for multi-axial coupling comprises: a plate tightly attached to a bone to be fixed and having one or more through-holes formed therein; an elevation nut having an annular shape with an inclined surface on the outer circumference to be inserted into the through-hole to be elevated along the inside of the through-hole; a fixing clip having a cut part formed on one side and inserted into the lower part of the through-hole to prevent the elevation nut from separating from the fixing hole; and the anchor screw inserted and anchored into the bone through the through-hole by screw coupling. As such, provided is the bone anchor assembly capable of fixing the anchor screw in various directions in accordance with the shape of the bone to be fixed, wherein a head of the anchor screw is fixed in the plate through-hole by elevation of the elevation nut, thereby providing an effect of stably fixing the head of the anchor screw in the through-hole regardless of axial direction.

Description

Bone anchor assemblies for multi-axial coupling}

The present invention relates to a fixing mechanism comprising a plate and a fixing screw to fix the bone for medical purposes, and more specifically, it can be fixed by variously changing the fixing screw bone insertion axial direction according to the surgical site and the situation. It relates to a bone fixation mechanism.

In general, in the case of a fractured patient, the fracture site is fixed by fixing the fracture site in place until it becomes a union of both bones to join the fracture site. In this case, there are a variety of methods, typically by attaching the plate to the bone surface and fixing the screw by fastening it to both sides of the fractured bone.

That is, by inserting a screw into the hole of the plate, the plate is pressed against the bone and fixed while being fastened with the bone.

On the other hand, recently, methods of fixing bones according to the state of the fracture and the affected area have also been diversified. That is, a bone fixation mechanism has been developed and used that has evolved from a conventional coupling method in which a fixing screw is vertically coupled to a plate, and can change the angle of the insertion shaft with respect to the plate according to the state of the bone.

The technique of fixing the fixing screws in various axial directions with respect to the plate eventually depends on ensuring that the heads of the fixing screws are stably fixed to the through holes of the plate even in various axial directions of the fixing screws.

As described above, various forms of the bone fixation mechanism capable of multi-axis fixation have been developed and applied, and a representative method is as follows.

First, as an example of a bone fixation mechanism capable of multi-axis fixation, there is a method in which a thread of the fixation screw head is formed only partially and combined with a plate.

In this case, there is a problem in that the bonding force between the fixed screw and the plate is weak, and when excessively applying a pressure input, cold bonding occurs between the fixed screw head and the plate, which causes difficulties in dismantling the fixed screw.

Another example of a bone fixation mechanism capable of multi-axis fixation is a method in which fixing holes of a plate are formed in various directions in advance.

In this case, there is a disadvantage that the fixing screws can be fastened only in a predetermined direction, and there is a problem that the fixing screws removal problem due to cold bonding cannot be solved.

Accordingly, in Korean Patent Publication No. 10-2001-0022371, as shown in FIG. 1, the bushing has a bushing with one side open in the hole of the plate and the bushing expands in the horizontal direction as the head of the fixing screw engages with the inside of the bushing. Therefore, it has been developed and disclosed in a technique for fixing screws to a plate hole.

However, the prior art as described above has the following problems.

That is, in the prior art, since the head of the fixing screw is fixed to the plate hole by the horizontal swelling of the bushing, there is a problem in that stable coupling cannot be achieved when the fixing screw has a predetermined inclination with respect to the plate.

Specifically, in the example shown in FIG. 1, the fixing screw on the right side is inserted in a predetermined inclined direction from the vertical direction with respect to the plate. In this case, the washer expands in an inclined direction within the hole in the plate and within the hole in the plate. Is pressed.

At this time, if the plate is shaken by an external force (when the left end is heard clockwise in the example shown), the washer leaves the press-fit position and does not exert full bonding force thereafter.

The problem of the separation of the washer is seriously generated when the inclined directions of a plurality of fixed screws fixed to the plate are the same, and is not greatly caused when the inclined directions of the fixed screws are varied.

Accordingly, when the present prior art is used in the medical field, in order to prevent the washer from disengaging from the position of the washer, there is a problem that an operation is performed by inserting excessively fixed screws in multiple directions unnecessarily.

(001) Republic of Korea Patent Publication No. 10-2001-0022371

The present invention has been devised to solve the above-described conventional problems, and the present invention provides a bone fixing mechanism capable of fixing the fixing screws in various directions according to the shape of the bone to be fixed, regardless of the axial direction of the fixing screws. It is intended to provide a bone fixation mechanism in which the fixing screw head can be stably fixed in the plate through-hole.

In addition, while the head of the fixed screw is stably fixed in the plate through hole, the present invention prevents the head of the fixed screw from directly engaging the through hole, thereby preventing a problem of cold bonding between the fixed screw and the plate. Is to provide.

According to a feature of the present invention for achieving the object as described above, the present invention is in close contact with the bone to be fixed, and one or more through-hole plate is formed; An elevating nut inserted into the through hole in an annular shape in which an outer periphery is formed as an inclined surface, and elevating and descending along the inside of the through hole; A cutting clip formed on one side and inserted under the through-hole to prevent the lifting nut from separating from the fixing hole; And through the through-hole, it is configured to include a fixing screw that is inserted and fixed to the bone through a screw connection.

At this time, the fixing screw, the body portion is formed with a main thread to be inserted into the bone; It comprises a head on which a fixing screw thread for screwing with a lifting nut inserted in the through hole is formed: an inner screw thread corresponding to the fixing screw thread may be formed on an inner circumferential surface of the lifting nut.

In addition, a plurality of through holes may be formed at different positions on the plate in different sizes.

In addition, the through hole may be formed as an inclined seating surface having an inclination in which the diameter becomes narrower as the inner surface goes from the bone bonding surface of the plate to the other side.

And on the inclined seating surface, a guide protrusion formed protruding into the through groove is formed; On the outer circumferential surface of the lifting nut, an outer guide groove into which the guide protrusion is inserted is formed; When the elevating nut is elevating, the relative rotation with respect to the through may be constrained.

In addition, a protruding jaw may be formed at an end of the lower surface side of the through hole to restrain the insertion of the fixed clip.

In addition, the lifting nut, the outer peripheral size is preferably formed to a size larger than the upper diameter of the through-hole, smaller than the lower diameter of the through-hole.

In addition, the elevating nut may have an outer inclined surface having different inclination angles.

In addition, the elevating nut may be formed such that the inclination angle of the outer inclined surface is linearly changed.

In the bone fixation mechanism capable of multiaxial coupling according to the present invention as described above, the following effects can be expected.

That is, the present invention provides a bone fixing mechanism capable of fixing the fixing screws in various directions according to the shape of the bone to be fixed, but the head of the fixing screw is fixed to the plate through-hole by the lifting of the lifting nut and fixed regardless of the axial direction. There is an effect that the screw head can be stably fixed in the plate through hole.

In addition, while the head of the fixed screw is stably fixed in the plate through-hole, the head of the fixed screw is coupled to the through-hole through a lifting nut, so that cold bonding does not occur between the fixed screw and the plate. It works.

1 is an exemplary view showing an example of a multi-axially coupled bone fixation device according to the prior art.
Figure 2 is an exploded perspective view showing the configuration of a bone fixation mechanism capable of multi-axis coupling according to the present invention.
Figure 3 is a cross-sectional view showing the inner configuration of the plate through-hole constituting the bone fixation mechanism according to the present invention.
Figure 4 is a perspective view showing an example of the lifting nut and the fixing clip constituting the bone fixing mechanism according to the present invention.
Figure 5 is an exemplary view showing a state in which the fixing screw is fastened in the plate through-hole in the bone fixing mechanism according to the present invention.
Figure 6 is a cross-sectional view showing another example of the lifting nut constituting the bone fixing mechanism according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described a specific embodiment of a bone fixation mechanism capable of multi-axis coupling according to a specific embodiment of the present invention.

Figure 2 is an exploded perspective view showing the configuration of a bone fixation mechanism capable of multi-axis coupling according to the present invention, Figure 3 is a cross-sectional view showing the inner configuration of a plate through hole constituting the bone fixation mechanism according to the present invention, Figure 4 is Is a perspective view showing an example of the lifting nut and the fixing clip constituting the bone fixing mechanism according to the present invention, Figure 5 is an exemplary view showing a state in which the fixing screw is fastened in the plate through-hole in the bone fixing mechanism according to the present invention , Figure 6 is a cross-sectional view showing another example of the lifting nut constituting the bone fixing mechanism according to the present invention.

First, as shown in Figure 2, the bone fixing mechanism according to the present invention is composed of a plate 100, a fixing screw 200, a lifting nut 300 and a fixing clip 400.

The plate 100 is attached to the bone to be fixed and is fixed to the bone by the fixing screw 200. To this end, the plate 100 has one or more through holes 110 for penetrating the fixing screw 200. It is formed.

The plate 100 is manufactured in various shapes and sizes according to the position and shape of the bone to be fixed, and in general, a plurality of through holes 110 are formed in different sizes to penetrate the fixing screws 200 at various locations. Can be.

At this time, the specific shape of the through-hole 110 will be described again with reference to FIG. 3.

On the other hand, inside the through-hole 110, the lifting nut 300 and the fixing clip 400 are inserted in the direction of the bone bonding surface of the plate 100 (hereinafter referred to as'lower surface').

The lifting nut 300 is configured to be moved up and down within the through-hole 110 in an annular shape with an outer periphery formed as an inclined surface, and the fixing clip 400 is formed with an incision 410 on one side. This is a configuration for preventing the lifting nut 300 from being separated from the fixing hole 110 under the through hole 110.

In addition, the fixing screw 200 is inserted into the bone is formed in the body portion 220 and the end fixed to the bone by screwing is coupled to the lifting nut 300 inserted into the through hole 110 head (head) 210), the main body 220 is formed with a main screw 221 for screwing with the bone, and the head 210 has a fixed screw for screwing with the lifting nut 300 ( 211) is formed.

Hereinafter, with reference to FIGS. 3 and 4, the configuration of the through hole of the plate according to the present invention and the configuration of the lifting nut and the fixing clip will be described.

3, the inner surface of the through-hole 110 has an inclined seating surface 111 having an inclination in which the diameter becomes narrower from the lower surface of the plate 100 to the other side (hereinafter referred to as the'upper surface'). Is formed into.

This is to interview the outer inclined surface 310 of the lifting nut 300 to be described later, so that the lifting nut 300 is fixed as the lifting nut 300 is elevated.

In addition, a guide protrusion 113 formed to protrude inside the through groove 110 is formed on the inclined seating surface 111.

The guide protrusion 113 is for restraining the rotation of the lifting nut 300 when the lifting nut 300 moves up and down, and the guide protrusion 113 is inserted into the side of the lifting nut 300. The guide groove 330 is formed.

On the other hand, a protruding jaw is formed at the bottom end of the plate 100 of the through hole 110 to prevent the fixing clip 400 from escaping outside the through hole 110 after the fixing clip 400 is inserted. It may be configured as possible.

Inside the through-hole 110 formed as described above, the lifting nut 300 and the fixing clip 400 as shown in FIG. 4 are sequentially inserted from the lower surface of the plate 100.

At this time, the elevating nut 300 has a circular ring shape, and an outer circumferential surface is formed with an outer inclined surface 310 inclined in a direction corresponding to the inclined direction of the inclined seating surface 111, and the fixed screw 200 is formed on the inner periphery. ), the inner screw thread 320 corresponding to the fixed screw thread 211 is formed.

Meanwhile, as described above, an outer guide groove 330 into which the guide protrusion 113 of the through hole 110 can be inserted is formed on the outer sloped surface 310.

Of course, in this case, a groove may be formed in the through hole 110, and it is also possible to form a protrusion corresponding to the elevation nut 300.

Here, the outer peripheral size of the lifting nut 300 is formed to be larger than the upper diameter of the through hole 110 and smaller than the lower diameter of the through hole 110, the lifting nut within the through hole 110 It is preferable that the lifting nut 300 is formed so that the lifting nut 300 does not fall out of the through hole 110.

On the other hand, the fixing clip 400 is a ring formed with an incision 410 on one side, and is restored after being inserted into the lower portion of the through groove 110 in an elastically deformed state, to the lower jaw of the through groove 110. It is limited to be seated and discharged out of the through groove 110.

Hereinafter, a process in which the fixing screw is fastened to the plate in the multi-axis coupleable bone fixation mechanism according to the present invention will be described in detail with reference to FIG. 5.

As shown in Figure 5 (a), the plate 100 is inserted into the lifting nut 300 inside the through groove 110, the fixing nut 400 is inserted into the lower end of the lifting nut 300 Fastening of the fixing screw 200 is started while the lifting nut 300 is being supported.

At this time, the fixing screw 200 is inserted by rotation to the bone to be fixed in a state where the body portion 220 first penetrates the through hole 110.

As the main thread 221 of the body portion 220 is inserted into the bone, the head 210 portion of the fixing screw 200 gradually approaches the through hole 110, and the fixing screw 200 head ( The fixed screw thread 211 of 210 is coupled to the inner screw thread 320 of the lifting nut 300.

Thereafter, if the rotation of the fixing screw 200 continues, as shown in FIG. 5(b), the lifting nut 300 is elevated along the inclined seating surface 111 of the through hole 110, and is press-fitted. The fixing screw 200 is fixed in a state in which it is no longer elevated.

At this time, even when the axial direction of the insertion of the fixing screw 200 is inserted in an inclined direction, the pressure input added to the lifting nut 300 is not released, unless the fixing screw 200 is rotated, the The fixing screw 200 is stably fixed in the through hole 110.

On the other hand, Figure 6 shows another embodiment of the lifting nut according to the present invention.

The lifting nut 300 ′ according to the present invention shown in FIG. 6 is formed at a different angle of the inclination angle of the outer inclined surface 310.

That is, as illustrated in FIG. 6, the outer inclined surface 310 is configured such that the inclined angle of the inclined surface changes linearly from the first outer inclined surface 310A, the inclination angle α1 to the second outer inclined surface 310B, the inclined angle α2. .

In this case, the lifting nut 300' is rotated while being elevated in the through hole 110 by being combined with the head 210 of the fixing screw 200, and the fixing screw 200 is inserted in an oblique direction. In this case, the inclined seating surface 111 of the through hole 110 is fixed in the direction in which it is in close contact with the press.

Accordingly, even when the fixing screw 200 is inserted in various inclined directions, the lifting nut 300' is fixed in a direction in which an optimal contact surface with the inclined seating surface 111 of the through hole 110 is formed. It has the effect of exerting a stable pressure input.

Of course, in this case, the guide protrusion and the outer guide groove that constrain the rotation of the lifting nut 300' are not formed.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

The present invention relates to a bone fixation mechanism that can be fixed by variously changing the axial direction of the fixed screw bone insertion according to the surgical site and the situation. In the present invention, the fixed screw can be fixed in various directions depending on the type of the bone to be fixed. Although there is provided a fixing mechanism, the head of the fixing screw is fixed to the plate through hole by the lifting of the lifting nut, so that the fixing screw head can be stably fixed in the plate through hole regardless of the axial direction.

100: plate 110: through hole
111: Inclined seating surface 113: Guide projection
200: fixing screw 210: head
211: fixing screw 220: body
221: Junasasan 300, 300': lifting nut
310: Outside slope 320: Inside thread
330: outer guide groove 400: fixing clip
410: incision

Claims (7)

A plate in close contact with the bone to be fixed and one or more through holes formed therein;
An elevating nut inserted into the through hole in an annular shape in which an outer periphery is formed as an inclined surface, and elevating and descending along the inside of the through hole;
A cutting clip formed on one side and inserted under the through-hole to prevent the lifting nut from separating from the fixing hole; And
Through the through-hole, a multi-axis coupling-capable bone fixing mechanism comprising a fixing screw that is inserted and fixed to the bone through a screw connection.
According to claim 1,
The fixing screw,
A body portion formed with a main thread inserted into the bone;
It comprises a head formed with a fixing screw for screwing with the lifting nut inserted into the through-hole:
On the inner peripheral surface of the lifting nut,
A multi-axis coupleable bone fixation mechanism, characterized in that an inner screw thread corresponding to the fixed screw thread is formed.
According to claim 2,
The through hole,
A multi-axis coupleable bone fixation mechanism, characterized in that the inner surface is formed as an inclined seating surface having an inclination in which the diameter becomes narrower toward the other side from the bone bonding surface of the plate.
The method of claim 3,
The lifting nut,
The outer periphery size is larger than the upper diameter of the through-hole, and a multi-axis coupleable bone fixation mechanism characterized in that it is formed to be smaller than the lower diameter of the through-hole.
The method according to any one of claims 1 to 4,
On the inclined seating surface,
A guide protrusion formed to protrude inside the through groove is formed;
On the outer peripheral surface of the lifting nut,
An outer guide groove into which the guide projection is inserted is formed;
A multi-axis coupleable bone fixation mechanism, characterized in that relative rotation with respect to the penetration is constrained when the lifting nut is elevated.
The method of claim 5,
At the lower surface end of the through hole,
A multi-axis coupleable bone fixation mechanism characterized in that a protrusion is formed to constrain the separation of the fixed clip inserted.
The method of claim 5,
The through hole,
A multi-axis coupleable bone fixation mechanism, characterized in that a plurality of different sizes are formed at different positions on the plate.

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