KR100534555B1 - Compression hip Screw - Google Patents

Abstract

The present invention relates to a compression screw, and more specifically, to prevent the compression of the compression screw used to treat hip fracture (hip fracture) by preventing too much compression of the hip fracture site. It is about pressure screw which can prevent.

An object of the present invention is to minimize the flow of the compression screw when the compression screw of the compression screw is fixed inside the barrel after the operation, even if the load of the human body is transmitted to prevent the hip fracture is too compressed to shorten the lower leg and At the same time, the possibility of reoperation can be lowered, and the patient is provided with a compression screw that can reduce the burden and pain on the surgery.

The configuration of the present invention for achieving the above object, the support plate is fixed to the femoral body and the hollow barrel is formed on the upper portion, the lagscrew coupled to the femoral head through the mounting hole formed in the barrel, and the mounting A compression screw including a compression screw fastened to the rack screw through a ball, characterized in that it further comprises a compression screw fixing means for fixing the compression screw to the mounting hole of the barrel.

Description

Compression Hip Screw

The present invention relates to a compression screw, and more specifically, to prevent the compression of the compression screw used to treat hip fracture (hip fracture) by preventing too much compression of the hip fracture site. It is about pressure screw which can prevent.

Hip joint, which is present inside the hip, is one of the largest weight-carrying joints in the human body, and the femur head is placed between the cartilage on the cup-shaped acebulum in the pelvis. In the ball-and-socket form, they are combined together.

In general, hip fractures such as femoral neck fracture, intertrochanteric femoral fracture, and subtrochanteric femoral fracture occur frequently in patients with osteoporosis due to external accidents such as traffic accidents and falls.

Such hip fractures are treated by fixing the fractures using a compression hip screw.

The pressure screw 100 is composed of a barrel 15, the support plate 111, the lag screw 20, the compression screw 30 is inclined at a predetermined angle as shown in FIG.

Here, a lag screw 120 into which the compression screw 117 is fitted in the form of a screwed fitting is slidably inserted into the barrel part.

The compression screw 117 serves to fix the lag screw 120 while sliding, and the lag screw 120 is manufactured in a cylindrical or hexagonal column, and both sides processing type is a thread formed on the inner surface of the compression It is engaged with the screw 117 and slidably fitted to the barrel 115.

A spiral 121 is formed at an end of the leg screw 120, and the leg screw 120 is moved forward / backward by the compression screw 117 to fix the fracture by penetrating the neck and the head of the proximal femur. do.

The support plate 111 is formed with screw holes 112 into which a plurality of fixing screws 113 are inserted, and is firmly supported on the femoral body by the fixing screws 113 to firmly support the screw 114. Will be

However, the compression screw 100 as described above is not fixed to the head portion of the compression screw 117, as shown in Figure 6 and 7, when the human body load is delivered after the operation of the compression screw 117 and the computer When the lag screw 120 is fastened to the ration screw 117 integrally, the movement of the inside of the barrel 115 is too much, the pressure of the femoral fracture site is too much, the length of the lower leg is shortened It became.

The present invention was devised to solve the above-mentioned problems, and an object of the present invention is to minimize the flow of the compression screw even if the load of the human body is transferred after surgery when fixing the compression screw of the compression screw inside the barrel. The hip fracture prevents shortening of the lower extremity and shortens the possibility of reoperation, and provides the patient with a compression screw that can reduce the mental burden and pain of surgery.

The configuration of the present invention for achieving the above object, the support plate is fixed to the femoral body and the hollow barrel is formed on the upper portion, the lagscrew coupled to the femoral head through the mounting hole formed in the barrel, and the mounting A compression screw including a compression screw fastened to the rack screw through a ball, characterized in that it further comprises a compression screw fixing means for fixing the compression screw to the mounting hole of the barrel.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a state of use of the pressure screw according to the invention, Figure 2 is an exploded perspective view of the pressure screw according to the present invention, Figure 3 is a partially enlarged cross-sectional view showing a compression screw fixing means according to the present invention. 4 is a partially enlarged cross-sectional view showing another embodiment of the compression screw fixing means according to the present invention.

As shown in the drawings, the pressure screw 1 of the present invention includes a support plate 11 having a screw hole 12 formed thereon so as to be fixed to the femoral body 2 with a plurality of fixing screws 13, and the support. The barrel 11 is provided to extend above the plate 11 and has a mounting hole 16 penetrated therein, and one side is slidably inserted into the mounting hole 16 of the barrel 15 and the other side is the femur. The lag screw 20 is formed on the inside of the lag screw (lag screw, 20) through the mounting hole 16 of the barrel 15 and the coupling portion 22 of the spiral portion is coupled to the two (3) It comprises a compression screw (compression screw, 30) fastened to the screw groove (23).

In addition, a compression screw fixing means for fixing the compression screw 30 to the mounting hole 16 of the barrel 15 is provided to support the lag screw 20 which is the main part of the present invention.

The compression screw fixing means is a male screw portion 31 formed in the head portion of the compression screw 30 and the female screw formed in the mounting hole 16 to be screwed to the male screw portion 31 as shown in FIG. It is comprised by the part 31.

In this case, the inner diameter of the mounting hole 16 is provided differently, thereby forming a step 16a due to the difference in the inner diameter, so that the compression screw 30 is rotated in the direction in which the female screw portion 31 is coupled. It will idle in idle state.

In addition, even if the compression screw 30 is in close contact with the step 16a, the male screw portion 31 and the female screw portion 32 have a short forward distance per revolution to minimize wear of the spiral portion. It would be desirable to form).

As another embodiment of the fixing means, it may be provided with a fixing bolt 40 is fastened to the inside of the mounting hole 16 as shown in Figure 4 to closely support the head portion of the compression screw 30, A spiral portion 18 is formed in the mounting hole 16 to fasten the bolt 40.

Here, the spiral portion is not formed in the head portion of the compression screw 30, the compression screw 30 is inserted into the barrel 15 to be fastened to the screw groove 23 of the lag screw 20. After that, the fastening bolt 40 is fastened to the spiral portion 18 so that the compression screw 30 does not flow, thereby closely supporting the head of the compression screw 30.

The fixing bolt 40 can be used to selectively use a variety of bolts, as an embodiment of the hexagonal groove is formed on one side is provided with a boltless bolt type without the head (두 部) of the bolt.

When explaining the operation and effects of the present invention configured as described above based on the procedure, hip fractures such as femoral neck fracture, intertrochanteric femoral fracture and subtrochanteric fracture due to external impact such as traffic accident or fall, etc. (Hip Fracture) If this occurs, internal fixation is performed using a compression hip screw (10).

This is to first determine the degree of damage, that is, the degree of crushing, dislocation of the posterior femoral neck wall, and then form a coupling groove 4 in the inner circumferential surface of the broken femoral ball head 3.

Subsequently, the lag screw 20 is fixed to the femoral ball head 3 by fastening the coupling part 22 of the lag screw 20 to the coupling groove 4.

As described above, the barrel 15 of the support plate 11 is mounted on the outer side of the lag screw 20 in a state in which the lag screw 20 is firmly fixed to the coupling groove 4 of the femoral ball head 3. In this case, the support plate 11 is mounted in parallel with the femur (2).

Here, the end faces of the inside of the lagscrew 20 and the barrel 15 has a hexagonal shape, respectively, when the barrel 15 is slidably fitted to the outside of the lagscrew 20, the support plate 11 ) Will not rotate left / right.

As described above, the barrel 15 of the upper part of the support plate 11 is fitted to the outside of the lag screw 20, and then the compression screw 30 is inserted into the mounting hole 16 of the barrel 15. It is fastened to the screw groove 23 of the lag screw 20.

At the same time, a male screw portion 31 is formed in the head portion of the compression screw 30 and is fastened to the female screw portion 17 formed in the mounting hole 16 of the barrel 15, wherein the compression screw ( The head portion of the head 30 moves forward along the female screw portion 17 and is intermittently rotated by the step 16a. When the compression screw 30 is rotated forward / backward in this state, the support plate 11 and the barrel are rotated. 15 is slid along the outer side of the lag screw 20 to move forward and backward.

That is, when the lag screw 20 is fixed to the femoral head (3) in the forward / reverse rotation of the compression screw 30, the compression screw 30 is fastened to the screw groove 23 or The support plate 11 and the barrel 15 are slid along the lag screw 20 to move forward and backward.

In the same manner as described above, while fixing the support plate 11 in close contact with the femoral body (2) by fastening the compression screw 30 to the screw groove (23).

Here, one end of the compression screw 30 is fastened and fixed to the screw groove 23 of the leg screw 20, and the head portion of the compression screw 30 is first and second spirals (31, 17) 2) is fixed by the two ends so that the compression screw 30 is not detached to the outside of the mounting hole 16 even after the load of the human body is transmitted, and the support plate 15 and the femur The distance between the head 3 can also be kept constant so that the support plate 11 is spaced apart from the femoral body 2, thereby causing damage to the femoral body 2 and the femoral head 3. Can be minimized.

That is, the compression screw 30 and the lag screw 20 is generated by the flow of the human body due to the coupling groove of the femoral ball head 3, the coupling portion 22 of the lag screw 20 is fastened It is possible to prevent the loss of the (4) or damage to the femoral body (2) by the fixing screw 13 for fixing the support plate (11).

In addition, as another embodiment for fixing the compression screw 30 to the mounting hole 16 of the barrel 15, as shown in Figure 4 without forming a spiral in the head portion of the compression screw 30, After forming the spiral portion 18 in the mounting hole 16 to maintain a constant distance between the support plate 11 and the femoral head 3, the fixing bolt 40 to the spiral portion 18 By fastening the head portion of the compression screw 30 will be able to support without flow.

Thereafter, the surgery is completed by firmly fastening the femoral body 2 with a plurality of fixing screws 13.

According to the present invention, the rack screw 20 is fastened to the femoral head 3 in which the fracture has occurred, and the compression screw 30 is brought into close contact with the support plate 11 to the femoral body 2. The support plate 11 and the femoral head 3 are fastened to the mounting hole 16 by fastening the screw 20 to the mounting screw 16 so that the compression screw 30 does not flow. Since the compression screw is not fixed as in the prior art and the compression screw and the lag screw flow inside the barrel by the load of the human body, the support plate is separated from the femoral body or the flow occurs in the leg screw. It is to solve the problem that the fracture site of the femoral body and femoral head is damaged, it is a very useful invention in internal fixation using a compression screw.

As described above, specific embodiments of the present invention have been described in detail, but those skilled in the art will appreciate that various modifications can be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be defined not only by the claims below, but also by those equivalent to the claims.

According to the present invention as described above, according to the present invention as described above, after the operation by fixing the compression screw to the barrel by the fixing means, the flow of the compression screw and the lag screw due to the human body load does not generate the femur There is an effect that can minimize the fracture of the fracture and femur of the head.

In addition, by minimizing damage to the fractures of the femoral head and the femoral body, the occurrence of reoperation can be delayed, and replacement can be made smoothly with a new compression screw during reoperation. There is an advantage that can reduce the mental burden and pain for surgery.

1 is a perspective view showing a state of use of the pressure screw according to the invention,

Figure 2 is an exploded perspective view of the pressure screw according to the invention,

Figure 3 is a partially enlarged cross-sectional view showing a compression screw fixing means according to the present invention,

Figure 4 is a partially enlarged cross-sectional view showing another embodiment of the compression screw fixing means according to the present invention,

Figure 5 is a separate perspective view showing a conventional pressure screw,

6 and 7 are cross-sectional views showing a flow state of a conventional compression screw.

<Description of Symbols for Major Parts of Drawings>

1: femur 2: femur body

3: femoral ball head 4: coupling groove

10: high pressure screw 11: support plate

12: screw hole 13: fixing screw

15: barrel 16: mounting hole

17: female thread part 18: spiral part

20: lag screw 22: coupling portion

23: screw groove 30: compression screw (compression screw)

31: male thread portion 40: fixing bolt

Claims (3)

A support plate fixed to the femoral body and having a hollow barrel extended thereon, a lag screw coupled to the femoral head through a mounting hole formed in the barrel, and a compression screw fastened to the rack screw through the mounting hole. In the pressure screw included, The compression screw is characterized in that it further comprises a compression screw fixing means for fixing the compression screw to the mounting hole of the barrel. The method of claim 1, wherein the compression screw fixing means, The compression screw is characterized in that the male screw portion is formed in the head portion of the compression screw, and the female screw portion is formed in the mounting hole and screwed together. The method of claim 1, wherein the compression screw fixing means, The fastening screw is fastened to the inside of the mounting hole, characterized in that the fixing bolt for tightly supporting the head portion of the compression screw.