KR20190115251A - Implant fixture with enhanced combination force to alveolar bone - Google Patents

Abstract

The present invention relates to a dental implant fixture to structurally prevent necrosis of bone or damage of the alveolar bone caused by occlusion pressure applied to the alveolar bone and a short supply of blood to the alveolar bone in existing implants. The dental implant fixture has various polygonal holes and a plurality of screw thread cutting units expanded and connected to screw threads and fixture body parts to supply blood well to the alveolar bone around a screw thread contact part, thereby increasing the bonding strength between the alveolar bone and the fixture under the stable structure without damage of the bone by the occlusion pressure applied to the alveolar bone during taking and masticating foods.

Description

Implant fixture with enhanced combination force to alveolar bone}

The present invention relates to an implant fixture that improves the bonding strength with the alveolar bone, and more specifically, by increasing the volume and volume of the alveolar bone around the fixture and the thread during the formation of new bone and the fusion process around the implant fixture. The present invention relates to an implant fixture having an increased bonding strength with the alveolar bone.

Dental implants refer to a series of procedures for implanting artificial teeth when natural teeth are lost.

To replace the lost roots (roots), a fixture made of titanium, etc., which is not rejected by the human body, is planted in the alveolar bone where the teeth fall out, and the artificial teeth are fixed to restore the function of the teeth. It is a procedure to make.

Such implants generally include fixtures implanted as artificial roots, abutments coupled to the fixtures, abutment screws securing the abutments to the fixtures, and artificial teeth coupled to the abutments. It is configured to include.

The fixture, which is a component of the implant, serves as an artificial tooth root as a part to be placed in a drill hole formed in the alveolar bone by using a drill or the like at the position where the implant is to be treated. Therefore, the fixture should be firmly placed in the alveolar bone.

Thus, a screw portion (threaded thread) is formed on the outer surface of the fixture so as to be firmly coupled to the inner wall portion of the alveolar bone forming the drill hole. The screw portion is inserted into the alveolar bone so that the fixture and the alveolar bone can be firmly coupled to serve to reinforce the fixing force of the fixture.

As such, the implant procedure involves placing a fixture on the alveolar bone using a drill, and then combining the abutment with the fixture when bone fusion proceeds, and finally putting an artificial tooth (prosthesis) on the fixture.

By the way, such a conventional implant fixture, there is a lack of blood supply to the alveolar bone around the thread, even if the bone fusion period for several months to heal the bone fusion to the alveolar bone does not proceed densely, the bone at the beginning of the implantation Even if bone fusion is created between the fixture and the fixture, excessive occlusal pressure is applied by food chewing, etc., and gum inflammation causes the alveolar bone around the fixture to damage after several years of use, leading to implant failure such as shaking and dropping of the fixture. Becomes

The most common causes of failure of a well-used implant are the excessive bite pressure on the fixture and the loosening of the bond between the alveolar bone and the implant. Insufficient blood flow may result in microfracture and alveolar bone destruction caused by damage to the alveolar bone, resulting in the implant falling out or shaking. 1 is a cross-sectional view showing a healthy implant and the progress of the inflammation and the implant in progress of further inflammation. Figure 2 is a photograph showing damage to the alveolar bone implanted.

Implant fixtures are made of metal or ceramic material and are non-blooded artificial structures that surround the bones thicker than natural teeth. If the thickness of the alveolar bone surrounding the implant fixture, which is a non-bleeding artificial structure, is less than 2 mm overall, alveolar bone necrosis or damage occurs and it is known that the implant is a major factor. 3 and 4 are cross-sectional views schematically showing a case where the thickness of the implant fixture and the surrounding alveolar bone is 2 mm or less. As shown in FIGS. 3 and 4, the peripheral bone of the implant fixture (alveolar bone) is at least 2 mm than that of the natural tooth. If the thickness is not thick enough, the alveolar bone necrosis or damage occurs a lot of the implant will fail.

5 is a view showing a comparison between the natural teeth and the implant, as shown in Figure 5, natural teeth (1) around the natural supply of blood can be supplied from the natural tooth (1) itself, blood in the gums (2) around the alveolar bone (4) (3) The supply of blood (3) to the alveolar bone (4) around the teeth is active, so the alveolar bone (4) around the teeth is healthy, but the implant fixture itself is an artificial structure of metal or ceramic material, so the blood (3) is supplied. This is impossible.

In particular, there is a high possibility that alveolar bone injuries 9 may occur due to insufficient supply of blood 3 to the deep bone between the screw around the fixture and the thread 7, and as shown in FIG. In the case of narrow alveolar bone 4, rapid fracture of the alveolar bone 4 is a major cause of implant failure. That is, around the existing implant fixture, the alveolar bone 4 is easily damaged with less blood supply.

Most implant surgery involves implantation fixtures with a diameter of 4 to 5 mm. In this case, the alveolar bone (4) with a narrow width of the alveolar bone (4) is about 5 to 7 mm. The lack of blood (3) supply in the area is often caused by peri-implantitis due to alveolar bone (4) damage and is a major factor in implant failure. In order to reduce the implant failure, it was difficult to perform alveolar bone graft, which is expensive, causes severe pain, and takes a long time to thicken the scarce alveolar bone. 7 shows a relatively narrow alveolar bone and a relatively wide alveolar bone, and FIG. 8 shows a state in which an implant is performed on a narrow alveolar bone, and an implant is applied to a narrow alveolar bone as shown in FIG. 7. If you want to reduce the failure of the implant to narrow the narrow alveolar bone costs a lot of cost, causing a lot of pain, such as problems occur, when the implant is performed in the alveolar bone lacking width as shown in FIG. As described above, the amount of blood (3) supplied to the implant thread (7) is insufficient, and peri-implantitis due to alveolar bone (4) damage frequently occurs and leads to implant failure.

FIG. 9 is a view showing a state of peri-implantitis, and as shown in FIG. 9, the blood supply to the deep alveolar bone (bone) between the peripheral thread and the thread around the fixture is insufficient, so that inflammation may occur around the fixture. Peri-implantitis causes the bones that hold the implant to melt and cause pain, and if the bone is lost to inflammation, the implant may need to be removed.

10 shows a case of implant failure due to alveolar bone injury around the fixture after the implant procedure.

As shown in Fig. 11 and 12, the black portion of the deep portion between the thread (7) of the fixture is a portion where the alveolar bone (4) is inflamed due to inflammation of the alveolar bone (4) because the blood (3) supply is not smooth As a major cause of implant failure. Most of the alveolar bone injuries 9 are caused by a poor supply of blood 3 from the entire alveolar bone 4 to the deep area alveolar bone (bone) between the two threads 7 of the fixture.

In the case of natural teeth, the supply of blood (3) proceeds smoothly through the natural tooth itself and the periodontal ligament to the alveolar bone (4) attached to the right side of the tooth to maintain healthy bones, but the implant fixture is made of metal, ceramic, etc. Because of the artificial structure of the bones located deep between the upper and lower threads of the fixture (7) is relatively small blood flow to the alveolar bone (4) is a lot of damage, such as implant shake, dropout failure.

Therefore, it is necessary to develop implant fixtures to smooth the blood supply to the alveolar bone around the fixture thread to minimize the damage to the alveolar bone of the patient and increase the blood flow to the alveolar bone around the fixture thread to increase the probability of success after implant placement. . If the thickness of the alveolar bone around the fixture cannot be more than 2 mm after implant implant placement, increase the contact area between the fixture and the alveolar bone as much as possible, and smooth the blood supply around the fixture screw thread. Inflammation or necrosis may be prevented. Means are needed to prevent inflammation or necrosis of the alveolar bone around the fixture.

An object of the present invention is to prevent the implantation process, new bone formation process, bone fusion process of the blood supply to the alveolar bone around the thread shortage, bone fracture, lack of bone formation, damage to the alveolar bone causes the implant failure, It is to provide a new configuration of implant fixture that is fused to the alveolar bone. In other words, the main object of the present invention is to minimize the damage to the alveolar bone of the patient and to increase the blood flow to the alveolar bone around the fixture thread, thereby increasing the probability of success after implant placement. It is to provide a new type of implant fixture that can strengthen the bonding force.

According to the present invention for solving the above problems, a fixture body; Threads provided on an outer circumferential surface of the fixture body; Threaded holes provided in the threads; Provided is an implant fixture that improves the bonding strength with the alveolar bone, characterized in that it comprises a; thread cutting portion provided in the thread.

The threaded hole is characterized in that arranged in a zigzag direction along the vertical direction.

The fixture body is provided with a concave groove, the thread cut portion is characterized in that extending to the concave groove.

The thread cutout extends from the end of the thread to the concave groove.

The thread cutting portion is characterized in that it is arranged in a zigzag direction along the vertical direction.

The thread cutting portion is configured to be arranged in a zigzag direction with a concave groove which is continued.

The screw thread is further provided with an extended threaded hole extending to the concave groove of the fixture body.

The extended threaded hole extends from the end of the thread to the concave groove at a position further entered.

The expansion thread hole is characterized in that it is arranged in a zigzag direction along the vertical direction.

The concave grooves in which the expansion thread hole is continued are also arranged in a zigzag.

The concave groove may be provided in plural on the outer circumferential surface of the fixture body.

The cutting portion is characterized in that a plurality provided on the screw thread.

The thread includes a front front thread portion and a rear cut portion in-point thread portion at the rear of the cutting portion, wherein a portion of the front end portion of the rear thread portion is thinner than the thickness between the upper and lower surfaces of the front thread portion, the thickness of which is smaller. It is characterized by consisting of a threaded portion.

According to the present invention, when the alveolar bone is formed around the fixture body and the thread by forming a thread cutting part, a fixture body fine groove, etc. in the fixture thread part, the alveolar bone between the thread and the thread as well as the bone surrounding the implant is increased. Therefore, it is possible to maintain the bones in a healthy state, so even if the width of the bones needed for implantation is narrow, implantation is possible, and alveolar bone grafts are not needed due to lack of bones. There are many advantages, such as reducing the cost of humans, saving the healing time until implants and the actual artificial teeth are used. When the bone fusion between the fixture and the alveolar bone, the thread cutout formed on the fixture thread and the fixture body fine part so that the fixture introduced into the alveolar bone and the alveolar bone can be more firmly coupled. Increasing the blood flow to the surrounding alveolar bone maintains the alveolar bone in a healthy state, shortening the implant treatment period and further enhancing bone fusion between the alveolar bone and the fixture.

1 is a cross-sectional view showing a healthy implant, an implant that has advanced inflammation, and an implant that has further advanced inflammation
Figure 2 is a photograph showing the damage of the alveolar bone implanted
3 and 4 are cross-sectional views schematically showing a case where the implant fixture and the surrounding alveolar bone lack a thickness of less than 2 mm (Source: https://blog.naver.com/guanine051/221100138504)
5 is a cross-sectional view showing a comparison between natural teeth and implants (Source: https://blog.naver.com/guanine051/221100138504)
6 is a photo showing a narrow alveolar bone
7 is a photo showing a narrow alveolar bone and a relatively wide alveolar bone
8 is a cross-sectional view showing a state in which the implant fixture is placed in the narrow alveolar bone
Figure 9 is a cross-sectional view and pictures showing the state of peri-implantitis (Source: https://blog.naver.com/guanine051/221100138504)
10 is a photograph showing an example of implant failure due to alveolar bone injury around the fixture after the implant procedure
11 and 12 are photographs for explaining the alveolar bone injury around the fixture after the implant procedure
FIG. 13 is a perspective view of an implant fixture according to the present invention, in which a threaded hole and an extended threaded hole are formed in a threaded portion and a recessed groove is formed in the fixture body.
14 is a perspective view of an implant fixture according to the present invention showing an embodiment in which a thread cutting portion is formed in a thread portion;
FIG. 15 is a perspective view of an implant fixture according to the present invention, in which a portion of a thread cut portion formed in a thread portion is extended to a concave groove of a fixture body; FIG.
16 and 17 is a perspective view of the implant fixture according to the present invention showing an embodiment in which the end of the thread cutting portion is formed as a curved portion
18 is a perspective view of an implant fixture according to the present invention showing an embodiment in which a thread cut portion formed in a thread is disposed at a position shifted up and down;
19 is a perspective view of an implant fixture according to the present invention, in which a portion of a thread cut portion formed in a thread is formed of an outer thread cut portion and an inner thread cut portion, and a portion of the inner thread cut portion extends to the concave groove of the fixture body.
20 is a side view of an implant fixture according to the present invention, showing an embodiment in which the thread cutouts formed on the threads are disposed at positions shifted up and down;
FIG. 21 is a side view of an implant fixture according to the present invention showing a state in which a thread cut portion formed in a thread is connected to a concave groove of an outer circumferential surface of the fixture body. FIG.
22 is a side view of an implant fixture according to the present invention, showing a modified embodiment of the thread cutout formed in the thread.
Figure 23 (a) is a side cross-sectional view showing an enlarged state of the front screw thread and the rear screw thread pushing the alveolar bone relative to the thread cutting formed on the thread when engaging the alveolar bone by rotating the fixture shown in FIG.
Figure 23 (b) is a side cross-sectional view showing a state in which a portion of the alveolar bone is recessed in the thread moving track groove after passing through the alveolar bone and the front and rear threads shown in (a) of Figure 22
Figure 23 (c) is a side cross-sectional view showing a state in which the rear threaded portion shown in Figure 22 (b) passes while pushing the alveolar bone recessed in the thread movement track groove.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. For example, if a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between each component. It is to be understood that another component may be "connected", "coupled" or "connected".

Referring to the drawings, the implant fixture according to the present invention is basically so that the blood (3) supply from the alveolar bone (4), which is a bone placed in the alveolar bone (4) to the deep portion of the thread (7) of the fixture smoothly made An enlarged threaded hole 11 is formed in the threaded portion 7, a recessed groove 10 is formed in the outer circumferential surface of the fixture body 6, and an extended threaded hole 11 extended to the recessed groove 10 in the threaded portion 7. The invention is characterized by the formation of). The present invention is also characterized in that the thread cutting portion 8 formed in the thread 7 extends to the concave groove 10 of the fixture body 6. In this case, since the alveolar bone 4 is filled to extend from the thread cutting portion 8 to the concave groove 10, the blood supply amount to the thread 7 portion is increased and the gap between the screw 7 and the alveolar bone 4 is increased. The bond strength can also be higher.

In the present invention, a threaded hole 5 is formed in an implant fixture threaded portion 7 (threaded wing portion), and a concave groove 10 (fixture body 6 fine groove) is formed on an outer circumferential surface of the fixture body 6. And an extended threaded hole (11) extending to the concave groove (10), the thread cutting portion (8) is an implant fixture extended to the concave groove (10) of the outer circumferential surface of the fixture body (6).

The thread 7 extends in a helical direction on the outer circumferential surface of the fixture body 6. When the fixture is viewed from the side, a plurality of threads 7 are arranged at regular pitch intervals in the vertical direction. When viewed from the side of the fixture body 6, the lowermost thread 7 is the first-level thread 7 and the upper thread 7 is the second-level thread 7. The threads 7 are N layers are provided on the outer circumferential surface of the fixture body 6. Preferably, the threaded holes 5 are formed in all the threads 7 of the N layers, and the threaded holes 5 are formed in plural for each of the threads 7.

The threaded hole 5 is configured to facilitate the blood supply from the alveolar bone 4 to the depth of the threaded 7 of the outer peripheral surface of the fixture body 6, wherein the threaded hole 5 is It penetrates from the top to the bottom.

A plurality of threaded holes 5 are formed in the threads 7 so that the alveolar bones 4 (bones) between the threads 7 and the threads 7 penetrate each other. A threaded hole 5 penetrating up and down is formed in each thread 7 of each layer of the outer circumferential surface of the fixture body 6 so that the fixture is placed in the alveolar bone 4 and the implant is in the state of being implanted. The alveolar bone 4 enters the hole 5 to create a bone connecting the upper and lower threads 7. A bone portion connecting the upper and lower threads 7 through the threaded holes 5 may be referred to as a connecting alveolar bone 4.

Accordingly, the size of the alveolar bone 4 (bone) in contact with the thread 7 by the connecting alveolar bone 4 formed through the threaded hole 5 formed in each thread 7 of the outer circumferential surface of the fixture body 6. As the blood supply increases by increasing the volume, the healthy alveolar bone 4 is maintained and the alveolar bone 4 is wrapped around the fixture like a net so that damage to the alveolar bone 4 due to occlusal pressure or periodontal inflammation occurs. This prevents the implant from failing, such as implant dropout and shaking.

On the other hand, in the present invention, a plurality of expansion thread holes 11 formed by extending connection to the concave groove 10 in various parts of the fixture thread 7 and the fixture body 6 in the various parts of the fixture thread 7 A plurality of thread cutouts 8 are formed which are extended and connected to the grooves 10, and the new alveolar bone 4 is formed during the bone fusion process after implant placement between the extended threaded holes 11 and the plurality of thread cutouts 8. The supply of blood (3) to the alveolar bone (4) between the upper and lower threads (7) increases, and the alveolar bone (4) is wrapped around the fixture like a net to increase the blood flow of the alveolar bone (4) in the thread (7) area to increase the occlusal pressure or periodontal Since the occurrence of damage to the alveolar bone (4) due to inflammation, etc., to eliminate the failure of implant dropout, shaking and the like.

In particular, an extended threaded hole is formed at a position that is further inward from the end of the screw thread (7), because the extended threaded hole (11) is formed by extending connected to the concave groove (10) in the present invention differentiated configuration from the hole As formed in the position entered further into the end of the screw thread 7 as well as the hole connected to the concave groove 10 of the outer peripheral surface of the fixture body 6 is referred to as expansion screw hole (11).

Since the alveolar bone 4 is generated and filled in all the portions extending from the extended threaded hole 11 to the concave groove 10, the alveolar bone 4 between the upper and lower threads 7 is formed as compared with only the hole formed in the screw thread 7. ) Increased blood (3) supply and alveolar bone (4) wrapped the fixture in a larger volume, such as a net, to increase the blood flow of the alveolar bone (4) in the thread (7) area, resulting in occlusal pressure or periodontitis Since the occurrence of damage to the alveolar bone 4 due to the back is more reliably prevented, it is possible to more reliably eliminate a failure such as an implant dropout or shaking. The alveolar bone 4 is not broken from the extension threaded hole 11 to the outer circumferential concave groove 10 of the fixture body 6, but the alveolar bone 4 is concave of the outer circumferential surface of the fixture body 6 from the extension screw 7. Since the groove 10 is continuously connected, the fixture body 6 and the thread 7 may be further increased in strength to be combined with the alveolar bone 4, and further, blood circulation may be increased.

It is also provided with a plurality of thread cutouts 8 extending into concave grooves 10 (i.e. fine grooves of the fixture body 6) in various parts of the fixture thread 7, and the thread cutouts 8 Since the alveolar bone 4 is formed from the concave groove 10 portion of the fixture body 6 to a net in a larger volume than when there is only a hole, the thread 7 7) Increase the blood flow of the area alveolar bone (4) more, thereby preventing the damage of the alveolar bone (4) due to occlusal pressure or periodontal inflammation more reliably, thereby more reliably eliminate the failure, such as implant dropout, shaking Can be. The alveolar bone 4 is not broken from the cut portion to the outer circumferential concave groove 10 of the fixture body 6, but the alveolar bone 4 is concave groove 10 of the outer circumferential surface of the fixture body 6 from the cut portion of the thread 7. Since it continues in succession, the fixture body 6 and the thread 7 is to increase the strength coupled to the alveolar bone 4 and further the blood circulation can be more.

Due to the configuration in which the extended threaded hole 11 extends to the concave groove 10 of the fixture body 6 and the cut portion extends to the concave groove 10 of the fixture body 6, it is simply a hole in the thread 7. Since the circulation of blood flow to the thread (7) and the fixture body (6) is significantly increased compared to the presence of only, the blood flow of the alveolar bone (4) of the thread (7) is further increased, which is caused by occlusal pressure or periodontal inflammation. Since the damage to the alveolar bone 4 is more reliably prevented, it is possible to more reliably eliminate a failure such as an implant dropout or a shake. The expansion thread hole 11 is a recessed groove 10 of the fixture body 6. The combination of the structure extending up to the concave groove 10 of the fixture body 6 by the combination of the fixture is placed in the alveolar bone 4 and then the main surface of the body of the fixture is inflamed. Synergies Will be effective.

At this time, the threaded hole 5 is disposed in the zigzag direction along the vertical direction. When the fixture body 6 is viewed from the side, the threaded hole 5 formed in the lower thread 7 is disposed at a position shifted from the threaded hole 5 formed in the upper thread 7. Based on the vertical direction of the fixture body 6, the threaded holes 5 formed in the upper thread 7 and the threaded holes 5 formed in the lower thread 7 are arranged at positions shifted from each other. . Thus, the threaded hole 5 is arranged in the zigzag direction.

If the threaded holes 5 are connected in a line up and down, the periodontal inflammation spreads all the way to the root end along the alveolar bone 4 of the threaded holes 5 connected up and down when the gum inflammation occurs, so that the fixture can be quickly eliminated. There is.

By the way, in the present invention, the threaded holes 5 are arranged in a jig between the upper and lower threads 7 as described above, and the alveolar bone 4 (bones) in the middle portion between the threaded holes 5 is also strong and inflamed. strong. In other words, the threaded holes 5 are arranged in a jig between the upper and lower threads 7 so that the threaded holes 5 are not connected in the upper and lower portions in a row, but between the threaded holes 5 formed in the upper and lower threads 7. Since the periodontitis spreads all the way to the root end along the alveolar bone (4) of the threaded hole (5), which is filled with (4) and connected to the top and bottom when the gum inflammation occurs, the inflammation even if the gum inflammation occurs Inflammation is limited only to a part of the alveolar bone 4, but it does not easily spread in a straight line up and down, so that there is no possibility that the fixture is quickly eliminated by periodontitis, and as a result, the inflammation is more resistant to inflammation. In other words, even though the periodontitis tries to spread downward through the threaded holes 5 formed in the thread 7 of the upper layer, the lower thread 7 serves as a shielding function to prevent the periodontitis from spreading. It's not just spreading more, it's limited to the top. On the other hand, even though the periodontitis tries to spread upward through the threaded holes 5 formed in the thread 7 of the lower layer, the upper thread 7 serves as a shielding function to prevent the periodontitis from spreading. It doesn't spread more and it's limited to the bottom.

On the other hand, preferably, the extended threaded holes 11 and the threaded cuts 8 are also arranged in positions deviated up and down in the zigzag direction when viewed from the side of the fixture body 6.

When the fixture body 6 is viewed from the side, the extended threaded hole 11 formed in the lower thread 7 is disposed at a position shifted from the extended threaded hole 11 formed in the upper thread 7. On the basis of the vertical direction of the fixture body 6, the extended threaded holes 11 formed in the upper thread 7 and the extended threaded holes 11 formed in the lower thread 7 are arranged at positions shifted from each other. It is. Thus, the extended threaded hole 11 is arranged in the zigzag direction. The concave groove 10 to which such an extended threaded hole 11 continues is also arranged in the zigzag direction.

Further, when the fixture body 6 is viewed from the side, the thread cutout portion 8 formed on the thread 7 in the lower layer is disposed at a position shifted from the thread cutout portion 8 formed on the thread 7 in the upper layer. Based on the vertical direction of the fixture body 6, the thread cutout part 8 formed on the upper thread 7 and the thread cutout part 8 formed on the lower thread 7 are disposed at positions shifted from each other. . Thus, the thread cutting portion 8 is arranged in the zigzag direction. This thread cut 8 extends from the end of the thread 7 to the recess 10. The concave groove 10 to which the thread cut portion 8 is continued is also arranged in the zigzag direction.

Therefore, even though the periodontitis tries to spread downward through the extended threaded hole 11 formed in the thread 7 of the upper layer, the lower thread 7 serves as a shielding function to prevent the periodontitis from spreading, so that the inflammation is from top to bottom. It is not limited to spreading more, but is limited to the upper part, and even though periodontitis tries to spread upward through the expansion thread hole 11 formed in the lower thread (7), the upper thread (7) prevents the periodontitis from spreading. Because the inflammation does not spread more from bottom to top, it is confined to the bottom. This means that the extension threaded holes 11 are also arranged in a zigzag form to be shifted up and down.

In addition, even though the periodontitis tries to spread downward through the thread cutout 8 formed in the thread 7 of the upper layer, the lower thread 7 serves as a shielding function to prevent the periodontitis from spreading. It is not limited to spread much but is limited only to the upper part, and even though the periodontitis tries to spread upward through the thread cutting part 8 formed on the thread 7 of the lower layer, the thread of the upper layer 7 prevents the periodontitis from spreading. Inflammation does not spread more from bottom to top, but only to the bottom. It is also meaningful to arrange the expanded thread cut part 8 in a zigzag form so as to be shifted up and down.

Meanwhile, in the present invention, the threaded hole 5, the threaded portion 7, the cutout 8, and the concave groove 10, which is a fine portion of the fixture body 6, are circular, elliptical, modified ovals of various forms, oblong, It is formed in various forms such as quadrangle and polygonal shape such as hexagon.

In this case, there is a difference in the area or volume of contact between the threaded holes 5, the cuts 8, and the recessed grooves 10, so that the supply of blood 3 can be increased more reliably, and the alveolar bone holding the fixture The structure such as the mesh of (4) can be further strengthened, and it is possible to completely eliminate the failure of the alveolar bone (4) due to the occlusal pressure and periodontal inflammation, the fallout of the implant, and the shaking. The shape of the alveolar bone (4) for holding the fixture body (6) and the thread (7) like a net can be varied, so that the structure of the net alveolar bone (4) for holding the fixture can be more robust, thereby Alveolar bone damage (4) due to pressure or periodontal inflammation, and the failure of implant dropout, shaking, etc. will be completely eliminated.

At this time, the end of the thread cutting portion 8 is made of a curved portion (CP) without being pointed. When the central part of the thread cut part 8 is referred to, the both ends of the thread cut part 8 are not pointed but configured as curved surfaces.

In the process of rotating the fixture of the present invention by turning the screw into the fixture insertion hole of the alveolar bone (4) (2) to be implanted, fine bone fragments by the pointed end edge of the thread cutting section (8) It does not occur, and the edge portion of the tip is curved, so that the alveolar bone 4 is smoothly outwardly (ie, outward from the center of the fixture body 6) without finely crushing the alveolar bone 4. ) As it is pushed and passed, it is possible to completely prevent the occurrence of inflammation or thickening in the alveolar bone (4) (2) after the implantation procedure due to the remains of fine bone fragments. In the process of positioning the alveolar bone (4) (2) by rotating the fixture of the present invention, the sharp end edge of the thread cutting portion (8) cuts the alveolar bone (4), thereby preventing the formation of fine bone fragments, fine bone It is possible to completely prevent the case that the engraving has a bad effect after the implant procedure.

At this time, in the present invention, the thread cutting part 8 is configured to include the outer thread cutting part at the front and the inner thread cutting part at the rear, and the shape and size of the outer thread cutting part and the inner thread cutting part are configured differently. For example, the outer thread cut and the inner thread cut may be combined to form an omega shaped thread cut 8.

Therefore, since the volume of the production alveolar bone 4 filled in the outer thread cutting portion and the inner thread cutting portion is formed in various ways, the supply of blood to the screw portion 7 is more smoothly, and the alveolar bone 4 and the thread ( 7) will be able to further strengthen the bond between.

At this time, as shown in FIG. 15, two or more inner thread cutting parts may be provided on the thread 7, and the innermost inner thread cutting parts may extend to the concave groove 10 of the fixture body 6. Can be configured. In this case, since the structure in which the thread 7 is coupled to the alveolar bone 4 can be simplified, and has two or more inner thread cutouts and an outer thread cutout, the alveolar bone 4 filled in the thread cutout 8 is provided. The volume of can be further increased to significantly increase the blood supply to the threaded portion 7 and to significantly increase the bond strength between the threaded portion 7 and the alveolar bone 4.

On the other hand, according to another embodiment of the present invention, the thread 7 includes a front threaded portion 5F at the front and a rear threaded portion 5R at the rear with respect to the threaded cut portion 8, and the rear threaded portion ( A portion of the front end side of 5R is constituted by a reduced threaded portion 5ER having a thickness thinner between the upper and lower surfaces than the thickness between the upper and lower surfaces of the front threaded portion 5F. It becomes the structure provided with the reduction thread part 5ER in the front part of the rear thread part 5R. The implant fixture of the present invention is placed by rotating in an implantation hole drilled in the alveolar bone (4), the alveolar bone (front) based on the thread cut portion (8) in the thread (7) during the rotation coupling process of the fixture 4) The portion of the thread 7 passing by rotating while pushing 4) becomes the front threaded portion 5F, and the portion of the thread 7 passing by rotating while pushing the alveolar bone 4 later from the rear becomes the rear threaded portion 5R. The thread cutting part 8 is provided in plural per thread 7 of one layer, and when the implant fixture of the present invention is rotated and placed in the alveolar bone 4, the alveolar bone 4 is first based on the thread cutting part 8. The thread 7 part passing while pushing) becomes the front thread part 5F, and the screw thread part 7 passing while pushing the alveolar bone 4 is constituted by the rear thread part 5R.

The front part (front part) of the said rear threaded part 5R is formed by the reduced threaded part 5ER thinner than the thickness of the upper and lower surfaces of the front threaded part 5F. Preferably, the reduced threaded portion 5ER has a tapered thread 7 shape when viewed from the side. In addition, when viewed from the side of the fixture body 6, the distal end portion of the reduced threaded portion 5ER is composed of a curved surface.

When the implant fixture of the present invention is coupled to the insertion hole of the alveolar bone 4, the screw cutting part 8 can prevent the bone fragments from being eaten by the alveolar bone 4.

When the implant fixture of the present invention is rotated to be placed in an implantation hole formed in the alveolar bone 4, the screw thread 7 of the outer circumferential surface of the fixture body 6 simultaneously rotates while pushing the alveolar bone 4 out of the alveolar bone 4. A thread 7 moving track groove is formed in the groove. See Fig. 23 (a).

Next, at least the upper alveolar bone 4 portion of the thread 7 moving track groove does not hesitate downward. As described above, the alveolar bone 4, which slumps down in the thread 7 moving track groove, may be referred to as a recessed alveolar bone 4. See FIG. 23 (b).

At this time, when the thickness between the upper and lower surfaces of the front end portion of the rear threaded portion 5R passing behind the front threaded portion 5F on the basis of the cut portion 7F is equal to the upper and lower thickness of the front threaded portion 5F, The rear threaded portion 5R may cut the recessed alveolar bone 4 while passing through the groove 7 moving track groove where the front threaded portion 5F is the first screw thread, and when the recessed alveolar bone 4 is cut, the bone fragments may be cut. This may cause inflammation around the fixture after the implant procedure.

By the way, in this invention, the front-end | tip part (front part of the rear thread part 7) of the rear thread part 5R which passes behind the front thread part 5F with respect to the said thread cutting part 8 is the front thread part 5F. Since the lower thread portion 5R is formed of a reduced thread portion 5ER that is thinner than the upper and lower thicknesses, the reduced thread portion 5ER is the recessed alveolar bone 4 when the rear thread portion 5R is turned behind the front thread portion 5F. Since it passes through the thread (7) moving track groove while naturally pushing up without cutting the portion, the bone fragments are prevented from being cut while eating the recessed alveolar bone (4), thereby preventing the bone around the fixture after the implant procedure. The bone fragments prevent inflammation in advance. In particular, since the reduced threaded portion 5ER is formed in a tapered shape with an inclined upper and lower surfaces, the recessed alveolar bone 4 is pushed up more smoothly, and the alveolar bone 4 under the recessed alveolar bone 4 is also eaten. It can be reliably prevented. Furthermore, the distal end of the reduced threaded portion 5ER is composed of a curved portion CP so that the sharp end of the reduced threaded portion 5ER cuts the recessed alveolar bone 4 in advance. See FIG. 23 (c).

When the reduced threaded portion 5ER provided in the rear threaded portion 5R is pushed up smoothly without cutting the alveolar bone 4 while rotating the fixture, the screwed thread 7 is engaged so that no broken bone fragments are generated. It is meaningful to avoid that, even if the blood supply is not properly supplied by the fine bone fragments, it is significant in that it completely prevents the inflammation around the fixture body (6) and the screw (7).

The terms "comprise", "comprise" or "have" described above mean that the corresponding component may be included unless specifically stated otherwise, and thus, other components are not excluded. It should be construed that it may further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms commonly used, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be interpreted in an ideal or excessively formal sense unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Therefore, since the embodiments described above are provided to completely inform the scope of the invention to those skilled in the art, it should be understood that they are exemplary in all respects and not limited. The invention is only defined by the scope of the claims.

1. Natural Teeth 2. Gum
3. Blood 4. Alveolar bone
5. Threaded holes 6. Fixture body
7. Thread 7F. Front thread
7R. Rear threaded portion 7ER. Reduction Thread
8. Thread cutting part 10. Concave groove
11. Expansion thread hole

Claims (8)

Fixture body 6;
Threads 7 provided on an outer circumferential surface of the fixture body 6;
Threaded holes (5) provided in said threads (7);
Implant fixture improved bond strength with the alveolar bone (4), characterized in that it comprises a; thread cutting portion (8) provided in the thread (7).
The method of claim 1,
Implant fixture improved coupling strength with the alveolar bone (4), characterized in that the threaded hole (5) is arranged in a zigzag direction along the vertical direction.
The method of claim 1,
The fixture body 6 is provided with a concave groove 10, the thread cutting portion 8 is an implant fix to improve the bonding strength with the alveolar bone (4), characterized in that extending to the concave groove (10). Chew.
The method of claim 3,
Implant fixture improved joint strength with the alveolar bone (4), characterized in that the thread cutting portion (8) is arranged in a zigzag direction.
The method of claim 1,
The screw thread (7) is further provided with an extended threaded hole (11) extending to the concave groove (10) of the fixture body (6) implant fixation to improve the bonding strength with the alveolar bone (4) Chew.
The method of claim 5,
Implant fixture improved coupling strength with the alveolar bone (4), characterized in that the expansion screw hole (11) is arranged in a zigzag direction.
The method of claim 3,
Implant fixture, characterized in that the concave groove 10 is provided in plurality on the outer peripheral surface of the fixture body (6).
The method of claim 1,
Implant fixture, characterized in that the cutting portion (8) is provided in plurality in the thread (7).

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