KR0148103B1 - Fractured bone stabilising fastener - Google Patents

Abstract

The present invention relates to an internal fixation device for fracture fixation that firmly fixes a fractured bone, and is coupled to a fractured bone and binds a fracture plate that firmly fixes the fractured bone to both fractured bones with screws, Absorb shock between the screw and protect the fracture, or insert a washer that disassembles after a certain period of time to reduce the joint strength of the internal fixation device to gradually transfer the external load to the bone. It is possible to stabilize the fracture without any symptoms.

Description

Fracture-resistant internal fixation device for joining fractured bones

1a to 1c is a view showing an example of a fracture healing apparatus according to the prior art

2 is a graph showing the change of stiffness with time of an ideal internal fixation device.

3a and 3b are views showing an embodiment of the fracture healing apparatus according to the present invention

* Explanation of symbols for main parts of the drawings

1a, 1b, 10a, 10b: fractured bone 2: gypsum bandage

3: metal tablet 4, 20: fracture plate

5, 23: screw 6, 7: junction

21: Insertion groove 22: Washer

24: head of screw 25: groove

The present invention relates to an internal fixation device for treating fractures by firmly fixing a fractured bone, and particularly, by inserting a washer of a material that absorbs an external shock or breaks down after a certain period of time between the fracture plate and the screw. The present invention relates to an internal fixation device for fracture therapy that can quickly and reliably heal fractured bones by allowing an appropriate load to be delivered to fractured bones even when the plate is installed.

Internal fixation devices, which are now widely used to join fractured bones, prevent joints from solidifying and promote healing of fractures.

However, after the fracture is cured and the fracture plate is removed, a refracture phenomenon occurs in which the bone in contact with the fracture plate is broken again.

Conventional methods of treating fractures are shown below. 1a and 1c are diagrams showing examples of a fracture treatment apparatus according to the prior art.

Figure 1a is a non-surgical treatment device for treating without surgery, a device using a plaster bandage (2) wrapped around the outside of the fractured bone (1a, 1b). Since this method is an indirect method that can not directly support a fractured bone, there is a limit to fracture treatment.

Figure 1b is a device for treating by inserting an intramedullary nail (3) into the interior of the fractured bone (1a, 1b), because the metal nail (3) used at this time can be applied only to simple fractures of the long bone There is a narrow range of treatments that can be done.

Figure 1c is a metal plate using the fracture plate 4 and the screw (5), by inserting a plurality of screws (5) to the bone as shown in the fracture plate (1a, 1b) across both sides of the fractured bone ( 4) is the most widely used method, and the range of treatment is also wide. However, the method using the fracture plate 4 and the screw 5 has a problem that the osteoporosis phenomenon that small holes are formed in the bone near the junction 6 of the fracture after the fracture treatment is completed. One of the main causes of such osteoporosis is due to the excessive rigidity of the metal fracture plate 4. That is, since the strength of the fracture plate 4 is about 10 times larger than that of the bone, most of the physiological load is transmitted to the fracture plate 4, and almost no bone is delivered to the bones 1a and 1b of the fracture site. Will not. As such, the bone absorbing action is vigorously generated at the unloaded portion due to the stress shield phenomenon in which the bone is not loaded, thereby causing small holes in the bone. This phenomenon causes a significant decrease in bone strength, resulting in re-fracture. Therefore, after performing the operation of removing the fracture plate 4, the user may experience the inconvenience of using an assistive device such as a crutch for a certain period of time, and in the case where the shock load generated by the movement of walking or the like is transmitted, the shock absorbing ability is reduced. Lack of bone damage caused by shock waves caused by the lack of fracture healing as well as the fracture plate (4) has a problem that is easy to break.

FIG. 2 is a graph showing the change in stiffness with time of the ideal internal fixation device, and shows the required characteristics of the ideal internal fixation device. In other words, an ideal fracture plate and screw fracture device, as shown in the graph, has sufficient strength, elasticity, and energy absorption ability to firmly fix the fracture site in the early stages of tissue healing, but over time Therefore, these traits should have the characteristic of disappearing. By doing so, the physiological load is transferred to the bone, thereby preventing bone absorption due to the stress shielding phenomenon, and reducing the possibility of re-fracture. In addition to these properties, the bones in the fracture area at the initial stage of fracture healing, that is, the bones that turn into hard bones as the healing progresses, are shocked because they are damaged by shock waves, especially tension waves, caused by movements such as walking. The nature of absorption is very important. In order to solve the problems in the conventional fracture healing apparatus as described above, various types of apparatuses have been developed. For example, devices such as low-strength plates, biodegradable fracture plates, and silicone rubber insert plates are examples of low-strength plates. In the case of biodegradable fracture plate, there are still many problems in practical application due to non-uniform extinction and decrease in strength due to water absorption. In the case of the silicone rubber insert plate, as in the low strength plate, it lacks the transfer of physiological loads, and even if a biodegradable insert plate is used instead of the silicone rubber, side effects due to non-uniform extinction and a large amount of extinction are expected. . Accordingly, the present invention, in particular in the healing device using a wider range of fracture plate and screws, in view of the above problems, has a shock-absorbing capacity between the fracture plate and the screw or a washer of biodegradable material Insertion has sufficient strength, elasticity and energy absorption in the early stages of tissue healing, but over time the washer decomposes, degrading the strength of the internal fixation device so that the load is gradually transmitted to the fractured bone, The purpose of the present invention is to provide an internal fixation device for fracture treatment that allows fast healing to proceed stably.

In order to achieve the above object, the present invention, in the internal fixation device for fracture therapy for bonding the fractured bone, combined with both bones of the fractured state and the fracture plate for firmly fixing the fractured bone, fracture the fracture plate It provides an internal fixation device for fracture treatment composed of a binding means for fixing to both sides of the bone and the washer inserted between the fracture plate and the binding means to be a stable treatment of the fractured bone.

Hereinafter, with reference to the accompanying drawings will be described in detail for the present invention. Figure 3a is an exploded perspective view of the fracture healing device according to the present invention, Figure 3b is a partial enlarged view of the screw and washer and fracture plate of Figure 3a, the fracture plate 20 in the figure according to C-C 'of Figure 3a It is a partial cross section. As shown in the figure, the internal fixation device for fracture treatment of the present invention is a fracture plate 20 is bonded to both sides of the fractured bone (10a, 10b), the fracture plate 20 fractured bone (10a, 10b), and a fastening means 23 fixed to the 10, and the washer 22 is inserted between the fracture plate 20 and the binding means (23). The fracture plate 20 uses a conventionally used metal plate, for example, a limited contact dynamic compression plate (hereinafter referred to as LCDCP), and inserts the appropriate size so that the washer 22 is easily inserted. A hole 21 is formed, and the insertion hole 21 is inserted into the insertion hole 21 such that when the screw 23 enters the bones 10a and 10b, the coupling force of the screw is applied toward the joint 7 of the bone. Of the outer peripheral surface 26 is inclined. The screw 23 inserted into the bones 10a and 10b through the insertion hole 21 of the fracture plate 20 is completely in close contact with the insertion hole 21 of the fracture plate 20. Is formed so as to surround the washer 22, it is configured in a good form of coupling with the washer (22). When the fixing plate 21 is fixed in the insertion hole 21 of the fracture plate 20, the washer 22 inserted between the fracture plate 20 and the screw 23 is a hole 25 into which the screw, which is the fastening means 23, is inserted. Is formed, the outer shape of the washer 22 is a form that can be inserted into the fixing hole 21 of the fracture plate 20 can be fixed, for example, is formed in a cylindrical shape whose diameter increases from the bottom to the top . In addition, the material of the washer 22 is a biodegradable material, for example, in the polymer (polymer) type, polyglycotic acid (hereinafter referred to as PGA), polyactic acid (hereinafter referred to as PLA), PLA / PGA copolymer, Poly-para Any one of a material of dioxanone (hereinafter referred to as PDS) or polymer with ceramic, tricalcuim phosphate (hereinafter referred to as TCP), hycroxyapatite (hereinafter referred to as HA) and porous calcium carbonite, argonite. In this case, the decomposition period of the biodegradable material is 1 to 2 years or more to adjust the decomposition characteristics as necessary. Next, the fracture plate 20 is fractured by tightening the screw 23 with the washer 22 therebetween until the head 24 of the screw 23 is inserted into the insertion hole 21 of the fracture plate 20. It is firmly fixed to the bone (10a, 10b). After the fracture plate 20 is coupled to the fracture portion 7, the washer 22 is gradually disintegrated as time passes, and the coupling force of the fracture plate 20 and the screw 23 is gradually decreased, and thus, from the outside. The given load is gradually transferred from the fracture plate 20 to the bones 10a and 10b so that the bone at the fractured site is in normal recovery. As described above, the internal fixation device for fracture treatment according to the present invention inserts a washer of biodegradable or similar material between the fracture plate and the insertion bolt to bind the fracture plate to both sides of the fractured bone. By progressively transferring external loads to the bone during the healing process, it is possible to significantly reduce the risk of re-fractures occurring in the device by conventional washer-free fracture plates and screws. In addition, the shock absorbing ability between the fracture plate and the screw is used to improve the shock absorbing ability at the fracture site. In addition, such shock absorption can prevent the delay of fracture healing caused by shock waves, in particular tensile waves, transmitted during the activity, it can also prevent the fracture of the fracture plate.

Claims (11)

In the internal fixation device for fracture therapy for bonding the fractured bone, A fracture plate for firmly fixing the fractured bone is coupled to the bone in the fractured state, And the binding means for fixing the fracture plate to the fractured bone on both sides, Insertion between the fracture plate and the binding means is an internal fixation device for fracture treatment, characterized in that consisting of a washer to be a stable treatment of the fractured bone. The internal fixation device for fracture treatment according to claim 1, wherein the fastening means is a screw. The internal fixation device for fracture treatment according to claim 2, wherein the head of the screw is wider than the upper part of the washer. The fracture fixing internal fixation device according to claim 1, wherein a mechanical compression metal plate (LCDCP) is used as the fracture plate. The internal fixation device for fracture treatment according to claim 1, wherein the washer is fixed on the fracture plate and a plurality of insertion grooves are formed through which screws pass. According to claim 5, The insertion groove formed in the fracture plate is an internal fixation device for fracture treatment, characterized in that the inner peripheral surface is inclined so that the coupling force of the screw acts toward the fracture portion of the bone. The internal fixation device for fracture treatment of claim 1, wherein the washer has a groove through which a screw penetrates, and whose outer diameter rises from the bottom to the top thereof, and has a cylindrical shape having a larger diameter. The internal fixation device for fracture treatment according to claim 1, wherein the washer is formed of a general polymer material having a shock absorbing ability. The apparatus of claim 1, wherein the washer is formed of a biodegradable material that decomposes over time. 10. The method of claim 9 wherein the biodegradable material is a polymer type, internal fixation device for fracture treatment, characterized in that any one of PGA, PLA, PLA / PGA copolymer, PDS The internal fixation device for fracture treatment according to claim 9, wherein the biodegradable material is a polymer with ceramic and is any one of TCP, HA, and Argonite.