KR200372954Y1 - Multi-Threaded Fixture - Google Patents

Abstract

The present invention relates to a screw-type fixture, and in particular, by forming a small screw thread on the ridge of the large screw thread formed on the outer circumferential surface of the fixture, the surface area is increased to secure a fixing force to the sponge bone and to concentrate stress concentrated on the large screw thread. It can be distributed evenly, and by forming the difference between the pitch of the thread and the outside diameter and the bone diameter of the portion buried in the cortical bone smaller than the sponge, the stress concentrated in the cortical bone can be dispersed to the sponge, preventing bone absorption and fusion A multi-threaded fixture that can promote the

Description

Multi-Threaded Fixtures

The present invention relates to a screw-type fixture, and in particular, by forming a small screw thread on the ridge of a large screw thread formed on the outer circumferential surface of the fixture, the surface area is enlarged to secure a fixing force to the sponge bone and at the same time a partial stress concentrated on the large screw thread It is possible to disperse the concentration, and by forming the difference between the pitch of the thread and the outside diameter and the bone diameter of the portion buried in the cortical bone smaller than the sponge, the stress concentrated in the cortical bone as a whole of the fixture can be distributed to the sponge, so that bone absorption A multithreaded fixture that can prevent and promote bone fusion.

Screw-type fixture is formed with a screw thread on the outer peripheral surface of the fixture body portion, it is used as a fixing member for fixing the prosthesis of the dental and orthopedic to the bone. Therefore, the screw-type fixture is screwed into a hole formed by a drill or the like in the bone tissue to fix the prosthesis. The hole is drilled slightly smaller than the diameter of the fixture. Cutting edges are formed in the fixture to form a female thread on the inner circumferential surface of the hole.

Bone tissue, as shown in Figure 2 consists of a cortical bone 81 and the cancellous bone (83). The spongy bone is relatively soft bone tissue inside the bone, and the cortical bone is harder than the spongy bone and generally forms a relatively thin film surrounding the spongy bone. Therefore, when the fixture is completely placed in the bone tissue, the length of the portion in contact with the cancellous bone is larger than the length of the portion in contact with the cortical bone (see Fig. 2).

One of the biggest problems that occur when using such a conventional screw-type fixture is bone absorption. Bone resorption refers to a phenomenon in which a degeneration occurs as the amount of bone tissue around the fixture is reduced. Such bone resorption may weaken the fixation force of the fixture, inhibit the stability of the prosthesis, and cause breakage of the prosthesis. In particular, bone resorption may deposit inflammation-causing tartar in the gum tissue surrounding the fixture when the fixture is used for dental use, or may downwardly grow the gum tissue along the exposed end of the fixture. Therefore, bone resorption is not preferable because it not only inhibits the stability of the prosthesis, but also does not look good.

The biological cause of bone resorption has not yet been elucidated. However, the stress acting on the adjacent bone tissue of the fixture is unevenly distributed, and it is recognized that both condensation and hypoallergenicity due to stress concentration promote bone absorption. Therefore, in order to prevent bone resorption and promote bone fusion between the fixture and the bone tissue, it is necessary to equalize the stress distribution.

The stress concentrations that cause the problem of bone resorption in fixtures are the overall stress concentrations that result from partial stress concentrations on individual threads and stress imbalances throughout the fixture. Partial stress concentration occurs centrally on pointed portions, such as ridges of threads, as shown in FIG. 8A. This partial stress concentration causes bone resorption of bone tissue adjacent to individual threads. Overall stress concentration refers to an uneven distribution of stress for fixtures embedded in cortical and cancellous bones, as discussed above, because bones consist of cortical and cancellous bones of different strengths. That is, when the fixture is implanted as shown in FIG. 2, more stress is concentrated in the cortical bone, which is the hardest part of the bone, and more bone absorption occurs in the cortical bone.

Conventional fixtures, as shown in Figure 1, the prosthesis (not shown), the head portion 13 is mounted, the screw portion 11 is placed in the bone tissue and the cutting edge 15 for self-tapping (self-tapping) ) The screw portion 11 is formed in a triangular or trapezoidal screw shape on the outer peripheral surface of the body portion of the fixture (1), generally a single thread 111 shape is formed over the entire body portion. Since the thread 111 is mainly implanted in the bones of relatively soft bone, in order to increase the fixing force of the fixture, as shown in FIG. 1, the pitch p and the outer diameter d1 and the bone diameter d2 of the thread 111 are as follows. It is a general trend to make a big difference.

However, as the difference between the pitch p and the outer diameter d1 and the rib diameter d2 of the thread 111 increases, the fixation force of the fixture increases, but the partial stress concentration on the individual threads increases.

Therefore, it is necessary to secure the initial fixation force of the fixture and to solve the problem of partial stress concentration on individual threads.

Since the threaded portion 11 of the conventional fixture 1 is formed with the same triangular or trapezoidal screws throughout the entire body portion, the stress is relatively higher than the cortical bone 81, which is a harder part than the sponge bone 83. The overall stress imbalance is concentrated. Due to the stress imbalance for the entire fixture, the bone absorption in the cortical bone is more generated in the spongy bone, the bone absorption in the cortical bone has a bad effect on the appearance as well as the stability of the prosthesis. Therefore, the need to prevent the bone absorption of the cortical bone by dispersing the stress concentrated in the cortical bone to the cancellous bone.

In addition, although the conventional fixture 1 is a triangular screw or a trapezoidal screw, the contact area between the fixture and the bone tissue is enlarged as compared with the cylindrical shape, but there is a need to further increase the contact area for the stability of the prosthesis.

The present invention is devised to solve the problems of the prior art as described above, the object of the present invention is to prevent the bone absorption and improve bone fusion by dispersing partial stress concentration on individual threads while maintaining the fixing force on the sponge It is to provide a fixture that can be done.

Another object of the present invention is to provide a fixture that can increase the adhesion to bone tissue by expanding the contact area to the bone tissue.

Another object of the present invention is to provide a fixture that can prevent the bone absorption of the cortical bone and promote bone fusion by distributing the stress concentration on the cortical bone to the spongy bone to distribute the stress evenly throughout the fixture.

1 is a perspective front view of a conventional fixture.

Figure 2 is a cross-sectional view showing a state in which the fixture shown in Figure 1 is placed in the bone tissue.

Figure 3a is a perspective front view of a multi-threaded fixture according to an embodiment of the present invention.

FIG. 3B is an enlarged view of portion “A” of FIG. 3A;

3C is a cross-sectional view of the fixture shown in FIG. 3A.

Figure 4a is a perspective front view of a multi-threaded fixture according to another embodiment of the present invention.

4B is an enlarged view of a portion “B” of FIG. 4A.

Figure 5a is a perspective front view of a multithreaded fixture according to another embodiment of the present invention.

FIG. 5B is an enlarged view of portion “C” of FIG. 5A;

Figure 6a is a perspective front view of a multithreaded fixture according to another embodiment of the present invention.

FIG. 6B is an enlarged view of portion “D” in FIG. 6A;

Figure 7a is a schematic diagram showing a state before the multi-threaded fixture of the present invention is embedded in bone tissue.

Figure 7b is a schematic diagram showing a state in which the multi-threaded fixture of the present invention is embedded in bone tissue.

Figure 8a is a stress distribution diagram showing the results of the FEM analysis for a conventional fixture.

8B is a stress distribution diagram for the threads in FIG. 8A.

Figure 9a is a stress distribution diagram showing the results of the FEM analysis for multi-threaded fixture according to an embodiment of the present invention.

9b is a stress distribution diagram for the threads in FIG. 9a.

The present invention has the following configuration to achieve the above object.

According to the first embodiment of the present invention, in the multi-threaded fixture of the present invention, in the screw type fixture, a screw thread formed on the outer circumferential surface of the fixture has a large screw thread and a plurality of small screw threads on the ridge of the large screw thread. Characterized in that formed.

According to the second embodiment of the present invention, the multi-threaded fixture of the present invention, in the screw-type fixture, the fixture has a cortical portion mainly located in the cortical bone after implantation and a sponge portion located in the cancellous bone, The sponge portion is characterized in that the outer circumferential surface is provided with a sponge-shaped large screw mountain and a sponge-shaped small screw mountain formed on the ridge of the sponge-shaped large screw mountain.

According to the third embodiment of the present invention, the multi-threaded fixture of the present invention, in the second embodiment, the cortical portion has a cortical small screw thread having the same pitch, valley diameter and outer diameter as the sea sponge small screw thread. It is characterized by.

According to the fourth embodiment of the present invention, the multi-threaded fixture of the present invention, in the second embodiment, the cortical portion cortex formed on the ridge of the cortical large screw acid and the cortical large screw acid extended from the spongy large screw acid It has a small screw thread, and the cortical small screw thread is characterized by more than the number of threads of the sponge small screw thread.

According to a fifth embodiment of the present invention, the multithreaded fixture of the present invention, in the fourth embodiment, the corrugated diameter of the cortical large screw thread is increased toward the upper portion so that the top diameter of the cortical small screw thread It is characterized by the same.

According to the sixth embodiment of the present invention, the multi-threaded fixture of the present invention, in any one of the second embodiment to the fifth embodiment, the vertical groove in the axial direction along the outer peripheral surface of the cortex portion It is characterized by a plurality formed.

Applicants will now be described in detail embodiments of the present invention with reference to the accompanying drawings.

3A is a perspective front view of a multithreaded fixture 2 according to an embodiment of the present invention, FIG. 3B is an enlarged view of a portion “A” of FIG. 3A, and FIG. 3C is inside the fixture 2 of FIG. 3A. It is sectional drawing which showed state. The fixture 2 shown in FIG. 3A is a dental internal type fixture that is implanted in the alveolar bone to fix the prosthesis. The fixture 2 has a cylindrical shape and is made of pure titanium and titanium alloy to promote bone adhesion between the bone tissue and the fixture. It is made of a biocompatible metal such as. The fixture 2 has a top end portion 21 protruding to the outside of the bone tissue after implantation, the body portion 23 located in the bone tissue, cutting edges 25 for self-tapping are sequentially formed from the top and the adapter inside The adapter seating groove 27 on which the (not shown) is seated and the screw fastening groove 29 on which the screw (not shown) is fastened are formed.

The top end 21 is located at the top of the fixture 2 and has a conical shape that is upwardly reduced. The top end 21 is the only part protruding to the outside of the bone after implantation of the fixture, preferably smaller than the entire length of the fixture.

The body portion 23 is a portion to be implanted in the bone when the fixture 2 is placed, the outer peripheral surface is formed with a thread. The screw thread is formed to have the same shape from the lower end of the body portion 23 of the fixture 2 to the upper end portion 21, and has a large screw thread 233, a large screw bone 234, a small screw thread 231, and a small screw thread. Has a screw bone 232.

The large screw thread 233 has a trapezoidal shape, and is formed with a single thread or two threads along the circumference of the body portion 23. The large screw thread 233 has an outer diameter d _c , a valley diameter d _a, and a pitch P _a . The large screw bone 234 is mainly embedded in the spongy bone to provide a fixing force to the fixture (2) with the large screw mountain (233). Therefore, it is necessary to form a large difference between the pitch P _a and the outer diameter d _c and the valley diameter d _a of the large screw thread 233. The pitch P _a of the large screw thread 233 is preferably 0.8 mm in consideration of the fixing force of the fixture, the workability of the small screw thread 231 and the small screw bone 232, and the like. The small screw mountain 231 and the small threaded bone 232 are formed on the ridge of the large screw mountain 233.

The small screw thread 231 is formed on the ridge of the large screw thread 233 and has an outer diameter d _e , a valley diameter d _b , and a pitch p _b as shown in FIG. 3B. The small screw thread 231 serves to alleviate partial stress concentration on the large screw thread 233 to prevent bone resorption and to widen the contact area between the fixture 2 and the bone tissue to provide a fixation force to the fixture 2. Do it. The rib diameter d _b of the small screw thread is larger than the rib diameter d _a of the large screw thread 233 and the outer diameter d _e of the small screw thread 231 is formed to be equal to the outer diameter d _c of the large screw thread 233. It is preferable. As a result of the experiment, compared to the conventional fixture having only a large screw thread 233 having a pitch of 0.8 mm, the multi-threaded fixture 2 of the present invention having two small screw threads 231 formed on the large screw thread 233 has a surface area. It can be seen that the increase by 7%. In the multi-threaded fixture 2 shown in FIGS. 3A and 3B, two small threaded threads 231 and one small threaded bone 232 are formed, but the number of rows of the small threaded threads 231 varies as necessary. You can change it.

The cutting edge 25 is formed by cutting a portion of the screw thread at the bottom of the body portion 23 in the axial direction to perform a self-tapping function. That is, when the groove is formed to be somewhat smaller than the diameter of the trunk portion 23 in the bone tissue to be implanted with the multi-threaded fixture 2, the cutting edge 35 is formed on the inner circumferential surface of the groove. Forms female thread.

The adapter seating groove 27, as shown in Figure 3c, has a cylindrical shape inclined downward and has a constant length from the top end 21 is formed in the body portion 23. The screw fastening groove 29 extends from the lower end of the adapter seating groove 27 in the axial direction, and a screw thread 291 for fastening a screw (not shown) is formed on an inner circumferential surface thereof.

Multithreaded fixture 3 according to another embodiment of the present invention, as shown in Figures 4a and 4b, the top end 31, the cortical portion 33, the surface portion 34, the cutting edge 35 ), The adapter seating groove 37 and the screw fastening groove (39). The overall shape and material of the multi-threaded fixture 3 are the same as the fixture 2 according to the embodiment shown in FIGS. 3A-3B. And the configuration and role of the top end 31, the cutting edge 35, the adapter seating groove 37 and the screw fastening groove 39 is a multi-threaded fixture 2 according to the embodiment shown in Figures 3a to 3b Since the uppermost portion 21, the cutting edge 25, the adapter seating groove 27 and the screw fastening groove 29 are the same as below, the cortical portion 33 and the surface portion 34 will be described below. .

The surface portion 34 is a portion mainly located in the surface bone when the implantation of the fixture (3) is completed, the length of the lower end of the fixture (3) has a length L1 on the outer circumference surface large screw thread (343) and sponge surface small A thread 341 is formed.

The sponge large screw thread 343 is formed over the entire outer circumferential surface of the sponge portion 34 and has an outer diameter d3, a rib diameter d1, and a pitch p1. The lower surface of the screw thread 341 is formed on the ridge of the large surface of the screw thread 343, and has an outer diameter d4, a valley diameter d2, and a pitch p2. Of course, the number of threads of the sponge screw thread 341 may be variously changed as necessary. The configuration and role of the large surface mount screw 343 and the small surface mount screw 341 is the large screw thread 233 and the small screw thread 231 of the multi-threaded fixture 2 according to the embodiment shown in Figures 3a to 3b. Is the same as

The cortical part 33 is a part mainly located in the cortical bone when the fitting 3 is completed, and has a predetermined length L2 between the uppermost part 31 and the sponge surface 34. The depth of cortical bone in human bone tissue varies, but generally does not exceed 3 mm. Accordingly, the length L2 of the cortical portion 33 is preferably formed to be 3.5 mm or less with a slight margin. A small cortical screw 331 is formed on the outer circumferential surface of the cortical portion 33.

As shown in Fig. 4B, the cortical small nasal acid 331 is formed over the entire cortical portion 33 and has an outer diameter d6, a valley diameter d5, and a pitch p4. The pitch p4 of the cortical small screw thread 331 is 1/4 of the pitch p1 of the large surface screw thread 343, and is equal to the pitch p2 of the small screw thread 341, and the number of rows of the cortical small screw thread 331 is increased. It is preferable to make the lead of the cortical small screw thread 331 and the sponge small screw thread 343 equal to four times that of the large sponge thread screw 343. And the corrugated diameter d5 and the outer diameter d6 of the cortical small screw thread 331 is formed the same as the corrugated diameter d2 and the outer diameter d4 of the sponge small screw thread 341, the spongy large screw thread 343 and the sponge screw thread 341 It is preferable to implant the fixture 3 continuously without damaging the female screw thread formed while buried in the bone tissue.

The cortical small screw thread 331 reduces the stress applied to the cortical portion 33 because the difference between the outer diameter d6 and the rib diameter d5 and the pitch p4 are smaller than that of the large screw thread 343. (34) to distribute the stress. Therefore, the cortical small screw thread 331 can disperse stress concentrations on cortical bones into sponges, thereby preventing bone resorption of cortical bones.

Multithreaded fixture 3 'according to another embodiment of the present invention, as shown in Figures 5a and 5b, the top end 31', cortical portion 33 ', the surface portion 34' , A cutting edge 35 ', an adapter seating groove 37', and a screw fastening groove 39 '. The surface portion 34 'has a large surface mount screw 343' and a small surface mount thread 341 'formed on the ridge of the large surface mount 343'. The cortical portion 33 'has a small cortical screw thread 331' and a cortical large screw thread 333 'on its outer circumferential surface. The rest except for the cortical part 33 'is the same as the configuration and role of the multi-threaded fixture 3 according to the embodiment shown in FIGS. 4A to 4B. Only the small cortical thread 331 'will be described.

The cortical large screw thread 333 'extends from the sponge large screw thread 343' and has an outer diameter d6 ', a rib diameter d5' and a pitch p3 '. The cortical large screw thread 333 'has a trapezoidal shape, and the cortical small screw thread 331' is formed on the ridge. The pitch p3 'and the number of rows of the corrugated large screw thread 333' are formed to be the same as the pitch p1 'and the number of the strings of the sponge large screw thread 343', so that the sponge large screw thread 343 'and the cortical large screw thread 333' It is preferable to make the lead of) the same.

The valley diameter d5 'of the cortical large screw thread 333' is gradually increased toward the upper portion of the fixture 3 'so that the valley diameter d5' at the top end is the valley diameter d7 'of the cortical small screw thread 331'. It was formed in the same manner as The outer diameter d6 'of the cortical large screw thread 333' is the same as the outer diameter d3 'of the sponge large screw thread 343'. Therefore, the difference between the outer diameter d6 'and the bone diameter d5' becomes smaller as the cortical large screw thread 333 'is moved upward, so that the stress concentration of the cortical portion 33' is higher than that of the conventional fixture 1. Will be reduced.

The cortical small screw thread 331 'is formed on the ridge of the cortical large screw thread 333' and has an outer diameter d8 ', a rib diameter d7' and a pitch p4 '. The cortical small screw thread 331 'is formed more than the number of rows of sponge small screw thread 341' formed on the outer circumferential surface of the sponge portion 34 ', so that stress concentration on the cortical bone is dispersed to the sponge bone. In the present embodiment, three small cortical threads 331 'are formed on the cortical large screw thread 331', but the number of formation of the cortical small screw thread 331 'may be variously changed as necessary.

Multithreaded fixture 3 "according to another embodiment of the present invention, as shown in Figures 6a and 6b, the top end 31", cortex 33 ", the surface portion 34", Cutting edge 35 ", adapter seating groove 37 ", and screw fastening groove 39 ". The outer surface of the surface portion 34 ", as in the embodiment shown in Figs. A large screw thread 341 "formed on the ridge of the large screw thread 343" is formed on the outer circumference of the cortical portion 33 ". And a small cortical thread 331 "is formed. Except for the vertical groove 335 "formed on the outer circumferential surface of the cortical part 33", the configuration and the role of the multi-threaded fixture 3 'according to the present embodiment are the same, and thus the vertical groove 335 "will be described below. ) Will be described only.

The vertical groove 335 ″ is a groove formed vertically at equal intervals over the entire outer circumferential surface of the cortical portion 34 ″ on which the small cortical thread 331 ″ is formed. The vertical groove 335 ″ is the small cortical thread. And a grid pattern on the outer circumferential surface of the cortical portion 34 ". Accordingly, the stress concentration on the cortical portion 33 "is distributed to the sponge 35" by the vertical groove 335 ", thereby preventing the stress concentration on the cortical bone.

Applicants will be described below with reference to Figure 7a and 7b for the placement process of the multi-threaded fixture 3 of the present invention.

As shown in FIG. 7A, a groove 85 into which the multi-threaded fixture 3 of the present invention is to be embedded is formed to fit the length of the fixture 3 by using a drill (not shown). The groove 85 is formed to be slightly smaller than the corrugation diameter d1 of the large threaded surface of the multi-threaded fixture 3. Therefore, when the fixture 3 is placed, the cutting edge 35 taps the inner circumferential surface of the groove 85 to form a female thread, and the fixture 3 is screwed to the female thread to be fixed to the bone. .

7B is a cross-sectional view showing a fixture 3 embedded in bone tissue. As shown in FIG. 7B, a part of the cortical part 33 is embedded in the cortical bone 81, and the sponge 34 is located in the spongy bone 83, and the upper end 31 is the cortical bone 81. Thus, the spongy large screw thread 343 implanted in the spongy bone 83 where bone tissue is soft provides a fixing force to the fixture 3, and partially stresses the spongy large screw thread 343. Concentration is dispersed by the sponge small screw thread 341. In addition, since the difference between the pitch of the thread and the difference between the outer diameter and the valley diameter is smaller than that of the large sponge thread 343, the stress applied to the cortical portion 33 is dispersed to the sponge portion 34, and the fixation is performed. It is possible to make uniform stress distribution over the whole chur.

Applicants will look at the effect of the present invention through the experiment below.

Experiment 1: Evaluation Using Finite Element Method (FEM) for Stress Concentrated on Threads of Fixtures

Experimental condition

The multi-threaded fixture and the conventional fixture of the present invention were respectively placed in the bone tissue having the cancellous bone and the cortical bone, and the abutment was bonded to the fixture, and 100N vertical stress was applied while fixing both ends of the bone. . At this time, a linear finite element analysis (Linear FEM analysis) was performed by using a 3G program of Plasso Tech Co., Ltd. for the threads of the fixture, and a mesh was applied to an auto mesh. The material and physical properties of the cortical bone, sponge bone and fixture used in the experiment are shown in Table 1 below.

part material Modulus of elasticity (GPa) Poisson's Fixture titanium 120 0.3 Cortical bone bone 13.7 0.33 Spongy bone bone 1.37 0.33

Experiment result

The stress distribution of the conventional fixture is shown in Figs. 8a and 8b, and the stress distribution of the multi-threaded fixture of the present invention is shown in Figs. 9a and 9b. As can be seen in Figures 8a and 8b, it can be seen that the stress is concentrated on the end of the thread of the conventional fixture. However, by forming small threads on the threads, it can be seen that as shown in FIGS. 9A and 9B, the stress concentrated on the large threads is dispersed into the small threads. Therefore, it can be seen that the multi-threaded fixture of the present invention can alleviate the stress concentration phenomenon than the conventional fixture to promote bone resorption and bone fusion.

Applicant has described the embodiments of the present invention, but various changes and modifications of the present invention should also be construed as falling within the scope of the present invention as long as the technical spirit of the present invention is implemented. For example, the fixture of the present invention can be used for orthopedic surgery as well as for dental implants. In addition, in the above embodiment, the internal type fixture has been described, but may be applied to the external type fixture.

The present invention can achieve the following effects by the above configuration.

The present invention has the effect of providing a fixture that can prevent bone resorption and improve bone fusion by dispersing partial stress concentration on individual threads while maintaining a fixed force on the cancellous bone.

Another object of the present invention is to enlarge the contact area to the bone can achieve the effect of providing a fixture that can increase the binding force to the bone tissue.

Another object of the present invention is to distribute the stress concentration on the cortical bone to the spongy bone to distribute the stress evenly throughout the fixture to prevent the bone absorption of the cortical bone and to provide a fixture that can promote bone fusion Have

Claims (6)

A screw-type fixture, wherein the thread formed on the outer circumferential surface of the fixture has a large screw thread and a plurality of small screw threads formed on the ridge of the large screw thread. In the screw type fixture, the fixture has a cortical part mainly located in the cortical bone and a sponge part located in the sponge bone after implantation, and the sponge part is formed on the ridges of the sponges on the outer circumference and on the ridges of the sponges on the sponges. Multi-threaded fixture characterized in that it comprises a. 3. The multi-threaded fixture of claim 2, wherein the cortical portion has a cortical small screw thread having the same pitch, valley diameter, and outer diameter as the spongy small screw thread. According to claim 2, wherein the cortical portion has a cortical large screw acid extending from the spongy large screw acid and the cortical small screw acid formed on the ridge of the cortical large screw acid, the cortical small screw acid is characterized in that more than the number of threads of the sponge Multi-threaded fixture. 5. The multi-threaded fixture of claim 4, wherein the corrugation of the cortical large screw thread increases toward an upper portion thereof so that the corrugation of the cortical small screw thread is the same at the top. The multi-threaded fixture according to any one of claims 2 to 5, wherein a plurality of vertical grooves are formed along the outer circumferential surface of the cortex in the axial direction.