KR20200080627A - Bone screw for flexible engagement of bone - Google Patents

Abstract

The present invention relates to a bone fixing screw having a greater diameter of a thread part of a screw end part than that of the other side body to form a predetermined separation space after penetration of the screw end part to secure mobility. According to the present invention, the bone fixing screw for penetrating plates attached to bones of both sides of a fracture surface to fix the plates to the bones to fix the broken bone comprises: a head having a head thread part formed on an outer circumferential surface to be screw-coupled to a fixing hole of the plate; a circular rod shape body extended from the inner end part of the head; an insertion thread part having a thread formed on the screw end part; and a withdrawn thread part formed by the insertion thread part and the body and screw-coupled to the bone to provide drawing force to the screw by rotation when the screw is drawn and removed. The diameter of the thread of the insertion thread part is greater than that of the body and the thread of the insertion thread part. Accordingly, when the screw is removed after a fracture portion is completely agglutinated, a screw coupling force between an external bone with hard tissue and the screw provides drawing force during all processes for withdrawing the screw, thereby providing an effect of stably removing the screw.

Description

Bone screw for flexible engagement of bone}

The present invention relates to a screw that is fixed to the bone of the bone by penetrating the plate to fix the fractured bone. More specifically, the screw end of the screw end is formed to be larger than the diameter of the other body, and then the screw end is penetrated. It relates to a screw for fixing the bone so that the separation space is formed to ensure fluidity.

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, in recent years, the method of fixing the bone according to the type of fracture and the affected area has also been diversified. That is, it is better to allow a slight flow between the fracture surfaces than to fix the fracture surface in an immobilized state or to fix the bones of a specific area to be immobilized in a fixed state. In order to apply, a technique for fixing a fractured bone while allowing a predetermined flow between fracture surfaces has been developed and applied to the clinic.

As such, the bone fixation method that allows flow between fracture surfaces can be largely divided into two types.

First, after the screw head portion is coupled to the plate, a method of enabling movement in the screw coupling axis direction is possible.

In this case, a method of fastening the screw head portion to the plate via a washer or forming a head portion of the screw in a slipperable spherical shape is applied.

However, in this case, the separation distance of the plate-side end of the fracture surface has an extremely small flow range, whereas the other end of the plate has a relatively large flow range, resulting in problems such as the fracture part contacting asymmetrically. This is revealing the limits.

Next, another method of fixing the flow between the fracture surfaces, the diameter of the screw portion of the screw end is formed larger than the diameter of the body portion on the head side, so that the through hole formed as the screw end passes through the bone is formed larger than the body portion It is a method of forming a predetermined space between the body part and the through hole after fixing the screw.

Such technical content is disclosed in the prior art US Patent Publication US 2006/0195099.

In the prior art, as shown in FIG. 1, a screw composed of a head portion 2, a body portion 3, and a screw portion 4 penetrates the plate 1 and is fixed after piercing the bone.

At this time, the screw portion 4 is fixed to the other exoskeleton (BO) portion after passing through the lateral exoskeleton (BO) and medial internal bone (BI) of the bone.

Here, the exoskeleton (BO) is formed of a hard bone tissue, and the exoskeleton (BI) is formed of a relatively soft tissue.

On the other hand, the portion through which the screw portion 4 penetrates is formed with a through hole corresponding to the diameter of the screw portion 4, the body portion 3 having a diameter smaller than that of the screw portion 4 is formed on the plate 1 side exoskeleton BO Is positioned so that the plate 1 can flow with respect to the bone at a spaced distance from the body.

This flow of the plate 1 is possible until the bone is created and the space between the body portion 3 and the through hole is filled.

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

That is, the prior art screw has a problem in that it does not exhibit a sufficient pulling force when removing the screw.

Specifically, the screw according to the prior art is drawn/removed by reverse rotation in a state where the union of the bone is completed, as shown in FIG. 2.

At this time, the threaded portion 4 is drawn through the exoskeleton (BO) and through the endoskeleton (BI), the endoskeleal (BI) has a relatively soft tissue structure, when the endoskeleal (BI) area in contact with the thread is divided, screwed This is not maintained and the problem occurs that the screw part 4 does not pull out the screw because it is idle.

In this case, the screw is pulled out and removed with a strong external force, and in this process, there is a problem in that secondary damage is caused due to great damage to the bone.

(001) US Published Patent US 2006/0195099

The present invention has been devised to solve the conventional problems as described above, and the present invention secures fluidity on a plate fixed by a difference in diameter between a through-hole and a screw body, which is generated while a screw portion of a screw end penetrates a bone. In the screw for fixing the bone to be provided, it is to provide a screw for fixing the flow of the bone to ensure a stable screwing force when removing the screw.

According to a feature of the present invention for achieving the object as described above, the present invention is to fix the fractured bone to the bone fixing screw for fixing the plate to the bone through the plate attached to the bone on both sides of the fracture surface In, the head screw portion is formed on the outer circumferential surface, the head screwed to the fixing hole of the plate; A circular rod-shaped body extending from an inner end of the head; An insertion screw portion formed by including a screw thread at the screw end; And it is formed between the insertion screw portion and the body, and comprises a drawing screw portion that is screwed to the bone upon removal of the screw to provide a pulling force to the screw by rotation: the thread diameter of the insertion screw portion, the It is formed with a diameter larger than the diameter of the body and the thread diameter of the insertion screw portion.

At this time, the head may be formed in a shape that increases in diameter toward the outer end.

Further, at the end of the insertion screw portion, a drill tip may be formed to drill bone when the screw is inserted into the bone.

In addition, the effective insertion length (l1) that is inserted into the bone after fixing the screw in the body may be formed shorter than the length (l3) of the insertion screw portion.

Further, after the screw is fixed, the withdrawal screw portion may be formed from the beginning portion of the bone inner through hole to the beginning portion of the insertion screw portion.

In addition, the thread diameter of the withdrawal screw portion may be formed to have an inclination that increases from the head side toward the insertion screw portion.

On the other hand, the thread diameter of the withdrawal screw portion, it is possible to be formed to increase from the head side toward the insertion screw portion, the increase rate increases from the head side toward the insertion screw portion.

In addition, the thread pitch of the withdrawal screw portion may be formed larger than that of the insertion screw portion.

In the screw for fixing the flow of bone according to the present invention as described above, the following effects can be expected.

That is, in the present invention, the fluidity of the fracture portion is secured through the through-hole having a larger diameter than the screw body generated while the insertion screw portion of the screw end penetrates the bone, thereby providing relatively high fluidity at the beginning of joining and as the bone is joined By gradually reducing the fluidity, there is an effect capable of providing an appropriate degree of fluidity according to the bonding step of the bone joint.

In addition, in the present invention, in the process of removing the screw after the fracture part is fully united, the drawing force of the screw is provided by the screwing force between the insertion screw portion and the exoskeleton of the screw end in the initial stage of withdrawal, and in the middle of the drawing, the drawing is formed in the screw body. Since the screw pulling force is provided by the screwing force between the screw part and the drawing side exoskeleton, and at the end of drawing out, the screw drawing force is provided by the screwing force between the screw end of the screw end and the drawing side exoskeleton. There is an effect that the removal of the screw can be stably performed by providing a pulling force due to the screw coupling force between the solid exoskeleton and the screw.

Figure 1 is an exemplary view showing an example in which the screw for fixing the bone according to the prior art is fixed to the fracture.
Figure 2 is an exemplary view showing a process in which the screw for fixing the bone according to the prior art is removed from the coalesced bone.
Figure 3 is a side view showing a first embodiment of the movable bone fixing screw according to the present invention.
4 is an exemplary view showing an example in which the first embodiment of the movable bone fixing screw according to the present invention is fixed to the fracture portion.
5 is an exemplary view showing a process in which the first embodiment of the movable bone fixing screw according to the present invention is removed from the coalesced bone.
Figure 6 is a side view showing a second embodiment of the movable bone fixing screw according to the present invention.
7 is an exemplary view showing an example in which the second embodiment of the movable bone fixing screw according to the present invention is fixed to the fracture portion.

Hereinafter, various embodiments of the movable bone fixing screw according to specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a side view showing a first embodiment of the movable bone fixing screw according to the present invention, Figure 4 is an exemplary view showing an example in which the first embodiment of the movable bone fixing screw according to the present invention is fixed to the fracture , FIG. 5 is an exemplary view showing a process in which the first embodiment of the movable bone fixing screw according to the present invention is removed from the coalesced bone, and FIG. 6 shows the second embodiment of the movable bone fixing screw according to the present invention Side view, Figure 7 is an exemplary view showing an example fixed to the fracture portion of the second embodiment of the movable bone fixing screw according to the present invention.

First, as shown in Figure 3, the first embodiment of the flow-type bone fixing screw 100 according to the present invention, the head 110, the body 120, the withdrawal screw portion 130 and the insertion screw portion 140 It is configured to include.

As shown, the head 110 is formed in a shape that increases in diameter toward the outer end, the head screw portion 111 is formed on the outer circumferential surface, the portion is screwed to the fixing hole 210 of the plate 200 .

In addition, the body 120 is a circular rod extending from the inner end of the head 110 and is formed with the smallest diameter over the entire screw 100.

In addition, the insertion screw portion 140 is formed at the end of the screw 100 to drill a bone when the bone of the screw 100 is inserted, the end is formed with a drill tip 150.

At this time, the outer diameter of the thread of the insertion screw portion 140 is formed larger than the diameter of the body 120, the flow distance of the head 110 is determined according to the difference in these diameters.

In addition, an extraction screw portion 130 is formed between the insertion screw portion 140 and the body 120.

The withdrawal screw portion 130 is a portion that is screwed with the bone when the drawing of the screw 100 is removed, so that a pulling force is generated in the screw 100 by rotation, and more precisely, the insertion screw portion 140 of the bone When located in the end bone (BI) portion, so that the withdrawal screw portion 130 is screwed to the exo bone (BO) portion of the bone so that the screw force of the exo bone (BO) portion of the bone and the screw is generated throughout the entire drawing process This is the part for.

Accordingly, the thread diameter of the withdrawal screw portion 130 is formed smaller than the thread diameter of the insertion screw portion 140, and is not combined with the bone when the screw 100 is inserted, and after the bone is coalesced, the screw diameter of the screw 100 is Only when removed, it should be screwed with the bone.

As described above, when all of the insertion screw portion 140 is located in the internal bone BI when the screw 100 is removed, at least a portion of the extraction screw portion 130 must contact the exoskeleton BO. Accordingly, the formation length of the withdrawal screw portion 130 is determined by the length of the body 120 and the insertion screw portion 140.

That is, after fixing the screw 120 of the body 120, the effective insertion length (l1) of the body 120 and the length (l3) of the insertion screw portion 140 except for the separation distance (D) spaced apart from the outside of the bone In contrast, the withdrawal screw portion 130 is formed from a position such that the effective insertion length l1 is less than or equal to the length l3 of the insertion screw portion 140 to the end of the insertion screw portion 140.

On the other hand, the thread diameter of the withdrawal screw portion 130 may be formed to have an inclination (α) in the form of getting smaller from the insertion screw portion 140 toward the body 120 side.

This is to allow the withdrawal screw portion 130 to be easily screwed into the bone when the screw 100 is drawn.

In addition, the thread pitch of the withdrawal screw portion 130 is preferably formed larger than the insertion screw portion 140.

This is when the screw 100 is pulled out, the insertion screw portion 130 is screwed to move the bone where the screw is moved, and then the insertion screw portion 140 is screwed to move, despite the screwing of the drawing screw portion 130 And it is to ensure that the insertion screw portion 140 is screwed to the bone of the same position stably.

Meanwhile, FIG. 4 shows a state in which the movable bone fixing screw according to the present invention is fixed to the bone government.

As shown in FIG. 4, the screw 100 is fixed to the fractured bone by screwing the insertion screw portion 140 through the exo-endoskeleton-exoskeleton of the bone to the other exoskeleton (BO).

At the same time, the head 110 of the screw 100 has a head screw portion 111 coupled to a fixing hole 210 of the plate 200 and coupled to the plate 200.

At this time, the withdrawal screw portion 130 having a smaller thread diameter than the insertion screw portion 140 is not screwed with the bone, and the separation distance between the holes of the screw 100 body 120 and the insertion screw portion 140 is ( S) is formed.

By the separation distance (S), the head 110 of the screw 100 is fixed to enable a predetermined flow between the through holes while being combined with the plate 200.

On the other hand, as the bone of the fracture portion (F) is united, the bone grows even at the separation distance (S), as shown in Fig. 5, the bone is formed in close contact with the entire screw 100.

Thereafter, when removing the screw 100, as shown in FIG. 5, when the head 110 is rotated in the reverse direction, the screw 100 is caused by a screwing force between the insertion screw portion 140 and the exoskeleton BO. ) Is drawn.

Then, when the insertion screw portion 140 deviates from the exoskeleton (BO) region and enters the endoskeleton (BI) region, the withdrawal screw portion 130 enters the exoskeleton (BO) region, and the withdrawal screw portion 130 and the exoskeleton The screw 100 is drawn by the screwing force between (BO).

As described above, in the process of removing the screw 100, any one or more of the insertion screw portion 140 or the drawing screw portion 130 is screwed with the exoskeleton BO, so that a stable drawing force can be always provided.

Meanwhile, FIG. 6 discloses a screw according to another embodiment of the present invention.

As shown in this, another embodiment of the screw 100' according to the present invention has basically the same configuration as the embodiment shown in FIG. 3, but the length of the withdrawal screw portion 131 is formed long.

That is, the withdrawal screw portion 131 is formed over the entire length up to the insertion screw portion 140, except for the separation distance D of the body 121, the withdrawal screw portion 131 is formed.

At this time, the configuration of the head 110 and the insertion screw 140 is the same as the embodiment shown in FIG. 3.

Accordingly, as shown in FIG. 7, when the screw 100 ′ is fixed to the bone of the fracture portion, the withdrawal screw portion 131 is located in the exoskeleton (BO) region on the plate 200 as well as the end bone (BI). Is done.

Accordingly, when the screw 100' is removed, the binding screw coupling force between the drawing screw portion 131 and the exoskeleton BO can be more stably secured.

However, the second embodiment of the screw 100' has a disadvantage in that the flow distance of the head 110 is shortened after fixing compared to the first embodiment.

That is, the flow distance of the head 110 is determined by the difference between the diameter of the body portion within a predetermined distance from the through-hole of the bone and the through-hole side, since the withdrawal screw portion 131 is formed to the vicinity of the inlet portion of the through-hole Accordingly, since the difference in diameter from the through hole is reduced, the flow distance of the head 110 is shortened.

In order to compensate for this, as shown in FIG. 6, the thread diameter of the withdrawal screw portion 131 may be formed to have an inclination β having an increasing shape from the head 110 side toward the insertion screw portion 140. .

At this time, the thread inclination of the withdrawal screw portion 131 may be configured to be linearly changed as illustrated in FIG. 6, and may be formed in a curved shape to more effectively secure the flow distance of the head 110. .

That is, the thread diameter of the withdrawal screw portion 131 increases from the head 110 side toward the insertion screw portion 140, but the increase rate thereof increases from the head 110 side toward the insertion screw portion 140 in two dimensions. It can be spherical in a curved shape.

In this case, the withdrawal screw portion 131 provides a coupling with the exoskeleton (BO) for providing a stable drawing force, while maximizing the difference between the through hole and withdrawing screw portion 131 diameter toward the through hole side of the head 110 It is possible to secure a sufficient flow distance.

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 screw for fixing a bone to form a larger space than the diameter of the other side of the screw end of the screw end, so that a predetermined spacing space is formed after the screw end is penetrated, thereby securing fluidity. In the process of removing the screw after it is fully coalesced, the screw coupling force of the stiff bone and the screw provides a pulling force in the process before the screw is taken out, so that the removal of the screw can be stably performed.

100, 100': Screw 110: Head
111: head screw portion 120, 121: body
130, 131: withdrawal screw portion 140: screw insertion portion
150: drill tip 200: plate
210: fixed hole BO: exoskeleton
BI: Nagol

Claims (7)

In order to fix the fractured bone through a plate attached to the bone on both sides of the fracture surface to fix the plate to the bone, in the bone fixing screw,
A head screw portion formed on an outer circumferential surface and screwed to a fixing hole of the plate;
A circular rod-shaped body extending from an inner end of the head;
An insertion screw portion formed by including a thread at the screw end;
It is formed between the insertion screw portion and the body, and comprises a drawing screw portion that is screwed to the bone when the screw is pulled out and provides a drawing force to the screw by rotation:
The thread diameter of the insertion screw portion,
Flowing bone fixing screw, characterized in that formed in a diameter larger than the diameter of the body and the thread diameter of the insertion screw portion.
According to claim 1,
The effective insertion length (l1) inserted into the bone after fixing the screw among the body,
Flowing bone fixing screw, characterized in that formed shorter than the length (l3) of the insertion screw portion.
According to claim 1,
The withdrawal screw portion,
After the fixing of the screw, a movable bone fixing screw, characterized in that it is formed from the beginning of the bone inner through hole to the beginning of the insertion screw.
The method of claim 2 or 3,
The thread diameter of the drawing screw portion,
Flowing bone fixing screw, characterized in that it is formed to have an increasing inclination toward the insertion screw portion from the head side.
The method of claim 4,
The thread pitch of the drawing screw portion,
A movable bone fixing screw, characterized in that it is formed larger than the insertion screw portion.
The method of claim 5,
At the end of the insertion screw portion,
When the bone of the screw is inserted, a movable bone fixing screw, characterized in that a drill tip is formed to drill the bone.
The method of claim 6,
The head,
Flowing bone fixing screw, characterized in that formed in a shape that increases in diameter toward the outer end.

Images