KR101905579B1 - Implant fixture - Google Patents

Abstract

The present invention relates to an implant fixture for dental implant to shorten duration of implant treatment. According to one embodiment of the present invention, the implant fixture comprises: a fixture body (6); a screw thread (7) provided on an outer peripheral surface of the fixture body (6); an inner hole (8) provided inside the fixture body (6); a thread cutting unit (11) formed on the screw thread (7); and a screw cutting unit hole (12) provided in the fixture body (6) to communicate with the inner hole (8) at the thread cutting unit (11).

Description

Implant fixture < RTI ID = 0.0 >

The present invention relates to an implant fixture, and more particularly, to an implant fixture that increases the volume of fixture and alveolar bone around the implant fixture and bone fusion process, enhances contact fusion area between fixture and alveolar bone, Thereby increasing the bonding strength between the alveolar bone and the alveolar bone.

A dental implant refers to a series of procedures for implanting an artificial tooth when a natural tooth is lost.

In order to replace the missing root (root), a tooth fixture, made of titanium or the like, which has no rejection to the human body, is planted in the alveolar bone that has exited the tooth, and then the artificial tooth is fixed to restore the function of the tooth .

Such an implant generally includes a fixture to be placed as an artificial root, an abutment to be coupled to the fixture, an abutment screw to fix the abutment to the fixture, and an artificial tooth .

The fixture, which is a component of the implant, serves as an artificial root, which is placed in a drill hole formed in the alveolar bone using a drill or the like at a position where the implant is performed. Therefore, the fixture should be securely mounted on the alveolar bone.

Thus, a screw thread is formed on the outer surface of the fixture so as to be firmly engaged with the inner wall portion of the alveolar bone forming the drill hole. These threads are inserted into the alveolar bone, thereby allowing the fixture and the alveolar bone to be firmly engaged, thereby enhancing the fixing force of the fixture.

In this way, the implant procedure is performed by placing a fixture on the alveolar bone using a drill, and then, when the fusion is completed, joining the alveolar bone to the fixture and finally covering the artificial tooth (prosthesis).

However, such a conventional fixture for implants has a problem in that osseointegration of the alveolar bone occurs even if the bone supply amount to the alveolar bone around the thread is insufficient and the contact area between the fixture and the alveolar bone is insufficient, Even if osseous fusion occurs between bone and fixture at the initial stage of implantation, excessive occlusal pressure is applied due to food chewing, etc., and when the gingival inflammation occurs, the alveolar bone around the fixture is damaged This is a major cause of implant failure, such as shaking or missing of fixture.

The reason for the failure of the well-used implants is the excessive occlusal pressure applied to the fixture and the loosening of the bond between the alveolar bone and the implant. If the bacteria in the oral cavity penetrate and cause inflammation, And microfracture (fracture of the alveolar bone) and alveolar bone destruction caused by lack of blood flow, causing the implant to fall or shake. FIG. 1 is a cross-sectional view showing the state of healthy implants and implants with progression of inflammation and the progress of inflammation. Fig. 2 is a photograph showing the alveolar bone defect implanted with the implant.

Since the implant fixture is made of a metal or the like and does not rotate, it needs to surround the surrounding bone more than the natural tooth. It is known that when the thickness of the alveolar bone surrounding the implant fixture, which is the artificial structure that does not pass through the blood, is less than 2mm as a whole, alveolar bone necrosis or damage is caused to a large extent and the implant is a failure factor. 3 and 4 are cross-sectional views schematically showing a case where the thickness of the implant fixture and the alveolar bone around the alveolar bone is 2 mm or less. As shown in Figs. 3 and 4, the bone around the implant fixture (alveolar bone) Or more, the implants fail due to the large amount of necrosis or damage to the alveolar bone.

FIG. 5 is a view showing a comparison between a natural tooth and an implant. As shown in FIG. 5, blood can be supplied from the natural tooth 1 itself around the natural tooth 1 and blood can be supplied from the gum 2 around the alveolar bone 4 (3) is supplied and the supply of blood (3) to the alveolar bone (4) around the teeth is active, so that the alveolar bone (4) around the teeth is healthy. However, since the implant fixture itself is an artificial structure made of metal or ceramic, This is impossible.

Particularly, there is a high possibility that alveolar bone damage occurs due to insufficient supply of blood 3 to the deep bone between the fixture peripheral thread and the thread 7, and as shown in Fig. 6, particularly in osteoporosis patients and narrow alveolar bone 4 ) Causes rapid failure of the alveolar bone (4), which is a major cause of implant failure. That is, around the existing implant fixture, the alveolar bone 4 is easily damaged by a less blood supply (less blood supply).

In most cases, implant fixation with a diameter of 4 to 5 mm is often applied. In this case, in the case of alveolar bone (4) with a narrow alveolar bone (4) width of about 5 to 7 mm, bone support and thickness are insufficient. (3) due to insufficient amount of blood (3) in the region of the alveolar bone (4), which is a major cause of implant failure. In order to reduce these implant failures, it was troublesome to perform alveolar bone graft treatment, which requires a long period of time for treatment, which is costly and causes severe pain to increase the thickness of the alveolar bone deficient. FIG. 7 shows a relatively narrow margin and a relatively wide alveolar bone. FIG. 8 shows a state in which an implant is implanted in a narrow alveolar bone. As shown in FIG. 7, the implant is implanted into a narrow alveolar bone In order to reduce the failure of the implant, it is expensive to increase the thickness of the narrow alveolar bone and cause severe pain. When the implant is applied to the alveolar bone lacking in width as shown in FIG. 8, As a result, the amount of blood (3) supplied to the region of the implant thread (7) becomes insufficient, resulting in frequent implant periostitis due to damage of the alveolar bone (4) and implant failure.

FIG. 9 is a view showing a state in which the implant periosteum is formed. As shown in FIG. 9, the supply of blood to the deep alveolar bone (bone) between the screw around the fixture and the screw thread is insufficient to cause inflammation around the fixture. If peri-implantitis occurs, the bones that hold the implant melt, causing pain. If the bone is lost due to inflammation, the implanted implant may need to be removed.

As shown in Figs. 11 and 12, the black part in the deep portion between the screw threads 7 of the fixture is not smoothly supplied to the blood 3, so that the alveolar bone 4 is irritated, Which is a major cause of implant failure. Most of the alveolar bone damaged portion IN occurs because the supply of the blood 3 from the alveolar bone 4 to the deep alveolar bone between the two screw threads 7 of the fixture is not smooth.

In the case of a natural tooth, the bone (3) is supplied smoothly through the natural tooth itself and the periodontal ligament to the alveolar bone (4) attached to the side of the tooth, and the bone remains healthy. However, Because of the structure, the blood flow is relatively small in the bones located deep between the screw threads (7) of the fixture, resulting in much damage to the alveolar bone (4)

Because of the anatomical structures such as maxillary sinus and hypochondrial nerve, it is difficult to place the fixture with a long length, and bone fixation force between the fixture and the alveolar bone (4), which resists the compression pressure, is insufficient.

Therefore, to minimize the damage of the alveolar bone of the patient and increase the blood flow to the alveolar bone around the fixture thread, the blood supply to the alveolar bone around the fixture thread is improved to increase the probability of success after implant placement, and the contact area between the fixture and alveolar bone is maximized Implant fixture for implantation. If the thickness of the alveolar bone around the fixture is small after implant fixture placement, maximize the contact area between the fixture and alveolar bone and smooth blood supply around the fixture thread to prevent inflammation or necrosis of the alveolar bone around the fixture It will be possible. Means are needed to prevent inflammation or necrosis of the alveolar bone around the fixture.

Open Patent Publication No. 10-2010-0090006 (Aug. 13, 2010) Published Japanese Patent Application No. 10-2015-0040776 (Apr. 15, 2015) Japanese Patent Application Laid-Open No. 10-2011-0084147 (July 21, 2011)

It is an object of the present invention to provide a method for preventing implant failure, which is caused by insufficient contact area or supply of blood to the alveolar bone around the threads in the implantation process, new bone formation process, and osseointegration process, , And to provide a new configuration of implant fixture that is firmly fused to the alveolar bone.

If the bone is absorbed by inflammation and the alveolar bone is insufficient, or an anatomical structure such as the maxillary sinus or the lower incisor nerve makes it difficult to place a fixture having a length of 10 mm or longer, a fixture having a short length may be placed, And to provide a fixture capable of having sufficient bone bonding force to withstand.

In other words, the main object of the present invention is to improve the blood supply to the alveolar bone around the fixture thread to improve the probability of success after implant placement by maximally reducing the patient's alveolar bone damage and increasing the blood flow to the alveolar bone around the fixture thread, And to provide a new configuration of implant fixture that can increase the contact area with the alveolar bone to enhance the bonding force.

According to an aspect of the present invention, there is provided a fixture body comprising: a fixture body; A thread provided on an outer circumferential surface of the fixture body; An inner hole provided in the fixture body; Internal threads provided in the internal bore; An inner ceiling concave-convex portion provided above the inner hole; A bottom surface irregular portion provided along the bottom surface of the fixture body; A thread cutting portion formed in the thread; And a thread cutout hole provided in the fixture body so as to communicate with the inner hole in the thread cutout portion.

And a threaded hole provided in the thread.

According to the present invention, a fixture body; A thread provided on an outer circumferential surface of the fixture body; An inner hole provided in the fixture body; And a body hole provided in the fixture body so as to communicate with the inner hole.

And a thread cutting unit provided in the thread.

According to the present invention, a fixture body; A thread provided on an outer circumferential surface of the fixture body; An inner hole provided in the fixture body; A body hole provided in the fixture body to communicate with the inner hole; And a threaded hole provided in the threaded portion.

According to the present invention, a fixture body; A thread provided on an outer circumferential surface of the fixture body; An inner hole provided in the fixture body; A body hole provided in the fixture body to communicate with the inner hole; A thread cutter provided in the thread; And a thread cutout hole provided in the fixture body so as to communicate with the inner hole in the thread cutout portion.

According to the present invention, a fixture body; A screw provided on an outer circumferential surface of the fixture body; an inner hole provided inside the fixture body; A body hole provided in the fixture body to communicate with the inner hole; A thread cutter provided in the thread; A screw cutout hole provided in the fixture body so as to communicate with the inner hole in the thread cutout portion; And a threaded hole provided in the threaded portion.

And the body hole and the thread cutting hole are formed with holes inclined at a predetermined angle toward the inner hole.

The present invention is characterized in that an inner hole is formed in the bottom surface of the fixture and a body hole is formed to be connected to the inner hole of the fixture so that the alveolar bone created in the inner hole of the bottom of the fixture contacts the alveolar bone outside the fixture via the fixture body hole Therefore, the blood flow to the alveolar bone around the implant is increased to maintain the alveolar bone in a healthy state, thereby shortening the period of the implant treatment and further strengthening the osseointegration between the alveolar bone and the fixture.

When the bones are absorbed by inflammation and the alveolar bone is insufficient or the anatomical structures such as the maxillary sinus and the lower incisor nerve make it difficult to place a fixture having a length of 10 mm or more, the above fixture having a large alveolar bone contact area and a large osseointegration area is short It is advantageous to hold the fixture at a sufficient level even if the fixture of the length is placed.

A body hole formed in the fixture body, an inner hole of the fixture body, an internal thread, an internal ceiling concave-convex portion, a fixture portion, and a fixture portion so that the fixture inserted into the alveolar bone and the alveolar bone can be more firmly engaged with each other during the fusion between the fixture and the alveolar bone. The alveolar bone is connected to the alveolar bone in the inner and outer portions by the undulations of the bottom surface provided along the bottom portion to increase the blood flow to the alveolar bone around the thread to maintain the alveolar bone in a healthy state and shorten the duration of the implant treatment, The core alveolar bone that is filled and held and the alveolar bone outside the fixture body are strongly connected and have the effect of further strengthening the osseointegration between the alveolar bone and the fixture.

FIG. 1 is a cross-sectional view showing a state of a healthy implant and an implant in which inflammation has progressed and an implant in which inflammation has further progressed;
2 is a photograph showing the damage of the alveolar bone in which the implant is placed
Figs. 3 and 4 are sectional views schematically showing the case where the thickness of the implant fixture and the alveolar bone around the alveolar bone is insufficient or less than 2 mm (source: https://blog.naver.com/guanine051/221100138504)
5 is a cross-sectional view showing a comparison between a natural tooth and an implant (source: https://blog.naver.com/guanine051/221100138504)
FIG. 6 is an X-ray photograph of a case where the maxillary sinus is large and the remaining alveolar bone for inserting the fixture is insufficient (Source: http://post.naver.com/viewer/postView.nhn?volumeNo=1432706&memberNo=15561528)
Figure 7 is a photograph showing a narrow alveolar bone and a relatively wide alveolar bone
8 is a sectional view showing a state in which an implant fixture is placed on a narrow alveolar bone
9 is a cross-sectional view showing a state in which the implant periosteum is formed and Fig.
FIG. 10 is a cross-sectional view showing a trapezoidal photograph used to form the hole portion of the fixture of the present invention during implant treatment
FIGS. 11 and 12 are photographs for explaining damage to the alveolar bone around the fixture after the implant treatment
13 is a bottom perspective view showing an embodiment in which an inner hole and a body hole are formed in an implant fixture according to the present invention.
14 is a cross-sectional view showing the structure of the main part shown in Fig. 13
Fig. 15 is a sectional view showing a state in which an alveolar bone formation promoting material is filled in an inner hole of the fixture body shown in Fig. 14
16 is a sectional view showing a state in which the implant is applied using the implant fixture of the present invention shown in Fig. 15
17 is a bottom perspective view showing an embodiment in which an inner hole, a body hole and a threaded hole are formed in the implant fixture according to the present invention.
18 is a bottom perspective view showing an embodiment in which an inner hole, a body hole, a threaded hole and a thread cut portion are formed in the implant fixture according to the present invention.
FIG. 19 is a bottom perspective view showing an embodiment in which an inner hole, a body hole, a threaded hole and a thread cut portion are formed in an implant fixture according to the present invention, and a thread cut portion hole is formed in a part of a plurality of thread cut portions;
FIG. 20 is a bottom perspective view showing an embodiment in which an inner hole, a body hole, a threaded hole and a thread cut portion are formed in the implant fixture according to the present invention,
FIG. 21 is a plan view showing an embodiment in which the body hole, which is a main part of the implant fixture according to the present invention,
Fig. 22 is a plan view showing schematically the inclination angle of the body hole shown in Fig. 21
23 is a plan view showing an embodiment in which the thread cutting hole, which is another essential part of the implant fixture according to the present invention,
Fig. 24 is a plan sectional view schematically showing the inclination angle of the thread cut hole shown in Fig. 23
25 is a sectional view of the alveolar bone showing the process of forming the alveolar bone into a fixture shape using the trepin bar and then placing the fixture after the alveolar bone drilling according to the present invention

Hereinafter, preferred 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 the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. For example, if a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, It is to be understood that other components may be "connected "," coupled "

Referring to the drawings, the implant fixture according to the present invention smoothly supplies the blood 3 from the alveolar bone 4, which is the bone to be implanted, to the deep portion of the screw 7 of the fixture, (3) The fixture body (6) is provided with an inner hole (8) and a body hole (9) so that the supply can be smoothly performed.

The inner hole 8 is provided with an internal thread 112 and an internal ceiling concave-convex portion 114.

A bottom surface concave-convex portion 116 is provided along the bottom portion (bottom portion) of the fixture body.

A first embodiment of the present invention includes an inner hole (8) of a fixture body (6), a thread cutout (11) and a thread cutout hole (12). The inner hole 8 of the fixture body 6 can be referred to as an inner hole 8 on the bottom surface of the fixture.

The inner hole (8) has an internal thread (112) and an internal ceiling concave-convex portion (114).

And has a bottom surface concave-convex portion 116 along the bottom surface portion of the fixture body.

A thread 7 is provided on the outer peripheral surface of the fixture body 6. The thread 7 extends in the spiral 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 a constant pitch interval in the vertical direction. If the lowest thread 7 is referred to as a single layer thread 7 and the next upper thread 7 as a double layer thread 7 when viewed from the side of the fixture body 6, And N layers on the outer peripheral surface of the fixture body 6.

The fixture body 6 is formed with a screw hole having a predetermined depth from the upper end toward the lower end and a screw shaft formed in the abutment is coupled to the screw hole to form an abutment ) Can be combined.

The inner hole 8 is formed in a hole shape having a predetermined height from the lower end portion to the upper end portion of the fixture body 6. A blocking portion is formed between the inner hole (8) and the screw hole. At this time, the inner hole 8 may have a cylindrical shape or a polygonal shape, and an inner thread 112 may be provided on a side surface thereof to widen the contact area with the inner alveolar bone.

The top surface of the upper portion of the inner hole 8 is provided with a concavo-convex pattern such as a columnar thread, a diagonal thread, a wavy or a checkered pattern so that the upper end of the alveolar bone and the fixture inner hole 8) an inner ceiling concave-convex portion 114 which serves to increase the contact area between the ceiling portions and increase the osseointegration area.

 The bottom surface of the inner hole 8 has a bottom surface irregular portion 116 such as a triangular shape, a wave pattern, or a serrated shape along the bottom surface of the fixture to widen the contact area with the alveolar bone, Self-tapping function is available.

The thread cutting portion 11 is provided in the thread 7. The thread cutting portion 11 is communicated from the distal end portion of the thread 7 to the proximal end portion. The thread cutting portion 11 is also communicated from the upper surface to the lower surface of the thread 7. A plurality of thread cuts 11 are provided along the threads 7 of each layer. The thread cuts 11 may be formed in all of the threads 7 of each layer or may be formed only in some of the threads 7 of the layer.

A screw thread cutout hole 12 is provided at the base end of the thread cutout 11 on the outer peripheral surface of the area of the inner hole 8 in the outer peripheral surface of the fixture body 6. The threaded cutout hole 12 is communicated from the base end of the thread cutout 11 to the inner hole 8. The thread cutting portion 11 is communicated from the distal end of the thread 7 to the outer circumferential surface of the fixture body 6 and extends from the outer circumferential surface of the fixture body 6 having the thread cutting portion 11 to the thread cutting portion hole 12, Is communicated with the inner hole (8).

Preferably, the thread cuts 11 are provided for each thread 7 of each layer. The thread cuts 11 may be formed entirely in the threads 7 of all layers or may be formed in the threads 7 of some layers. In the other embodiments of the present invention described below, the configuration of the thread cut portion 11 is the same.

The second embodiment of the present invention is characterized in that the inner hole 8 of the fixture body 6, the thread cut hole 12 and the threaded hole 10, the internal thread 112, the internal ceiling concave- (116).

The threaded hole 10 is formed to penetrate from the upper surface of the thread 7 to the lower surface. A plurality of threaded holes (10) are provided along the thread (7). At this time, the threaded hole 10 may be formed in the thread 7 of each layer or may be formed in the thread 7 of some layer among the threads 7 of each layer.

The third embodiment of the present invention includes the inner hole 8 and the internal thread 112 of the fixture body 6, the inner ceiling concave-convex portion 114, the bottom surface convex-concave portion 116, and the body hole 9 .

The body hole (9) is communicated from the outer peripheral surface of the fixture body (6) to the inner hole (8). The body hole 9 communicates with the inner hole 8 from the outer peripheral surface between the threads 7 provided in the inner hole 8 region. Preferably, the body holes 9 are provided along the outer circumferential surface of the fixture body 6.

The fourth embodiment of the present invention includes an inner hole 8 and an inner thread 112, an inner ceiling concave-convex portion 114, a bottom surface concave-convex portion 116, a body hole 9, and a thread cutting portion 11. The thread cutting portion 11 is provided in the thread 7 as in the first embodiment. The thread cutting portion 11 is communicated from the distal end portion of the thread 7 to the proximal end portion. The thread cutting portion 11 is also communicated from the upper surface to the lower surface of the thread 7. The configuration of the thread cutout 11 of the fourth embodiment is the same as that of the thread cutout 11 of the first embodiment.

The fifth embodiment of the present invention is characterized in that the inner hole 8 and the inner thread 112 of the fixture, the inner ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, the body hole 9, and the threaded hole 10 . The configuration of the inner hole 8 and the internal thread 112, the internal ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, and the body hole 9 in the fifth embodiment of the present invention is similar to that of the above- . The configuration of the threaded hole 10 of the fifth embodiment is the same as that of the threaded hole 10 described in the second embodiment.

The sixth embodiment of the present invention is characterized in that the inner hole 8 and the internal thread 112 of the fixture body 6, the internal ceiling concave-convex portion 114, the bottom surface concave- convex portion 116, the body hole 9, 7) Include cut-off holes. The configuration of the inner hole 8 and the internal thread 112, the internal ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, the body hole 9, and the thread 7 cut- Are the same as those of the inner hole 8, the body hole 9 and the thread 7 cut surface hole described in the embodiment.

In the seventh embodiment of the present invention, the inner hole 8 and the inner thread 112 of the fixture, the inner ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, the body hole 9 and the thread cutting portion 11 Threaded cutout aperture (12) and threaded hole (10). In the seventh embodiment, the inner hole 8, the internal thread 112, the internal ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, the body hole 9, the thread cut portion 11, And the threaded hole 10 are formed by the inner hole 8 and the inner thread 112 described in the above embodiments, the inner ceiling concave and convex portion 114, the bottom surface concave and convex portion 116, the body hole 9, The cutouts 11, the threaded cutouts 12 and the threaded holes 10 are similar.

The fixture according to the present invention having the above-described structure is rotated by being screwed into a hole drilled in the alveolar bone 4 and then placed. Then, an abutment is coupled to the fixture body 6, ) To the crown 5 (artificial tooth) to perform the implant treatment.

Meanwhile, in the present invention, the inner hole 8 may be filled with a bone formation promoting material 22. The bone formation promoting material 22 may be a bone fragment, an artificial bone, a collagen, or the like formed when the implant hole is punctured in the alveolar bone 4 for implanting the implant fixture. The bone formation promoting material 22 may be any material capable of forming the alveolar bone 4 in the inner hole 8. Of course, the alveolar bone formation promoting material 22 may optionally implant the implant without filling the alveolar bone formation promoting material 22 into the inner hole 8. [

At this time, when the bone is absorbed by inflammation or the like and the alveolar bone is insufficient, or it is difficult to place the fixture having a length of 10 mm or more due to the anatomical structure such as the maxillary sinus and the hypothalamic nerve, The first drilling hole of the alveolar bone is formed so as not to be too deep (forming a primary drilling hole so that the depth is 10 mm or less), and only the periphery of the primary drilling hole is drilled at the bottom of the primary drilling hole Next, the implant fixture of the present invention is placed in the primary perforation hole. At this time, the height of the upper and lower ends of the implant fixture of the present invention is a height of 10 mm or less, and the inner hole formed in the fixture body is coupled to the remaining alveolar bone inside the annular perforation hole formed below the bottom of the primary perforation hole , And is connected to the annular perforation hole from a bottom surface (lower end portion) of the fixture body up to a predetermined height portion. The inner perforated protruding portion, the internal thread 112 and the bottom surface protruding / And the fixture of the present invention can be maximized.

The body hole 9 is communicated from the outer peripheral surface of the fixture body 6 to the inner hole 8 so that the inner hole 8 and the body hole 9 are connected to each other. As shown in Fig. 22, the body hole 9 is constituted by a hole inclined at a certain angle (a) toward the inner hole 8.

When the fixture body 6 is cut to form the body hole 9, the cutting angle a is given. The cutting direction of the body hole 9 of the fixture body 6 is a cutting angle corresponding to the rotational direction when the fixture is placed. Specifically, the body hole 9 is inclined with respect to a tangent line passing the outer end of the body hole 9 when the fixture body 6 is viewed in a flat section. The body hole 9 is sloped from the outer peripheral surface of the fixture body 6 to the inner hole 8 such that the angle a between the center line of the body hole 9 and the tangent line is an acute angle range. In the figure, when the thread 7 is in the right-hand screw direction, the body hole 9 is sloped. When the fixture body 6 is rotated in the right-hand direction, a bone piece generated when the thread 7 pushes or cuts the alveolar bone 4 abuts on the inclined body 9 to the inner hole 8 Can be introduced. 21 to 24, the arrow direction RD indicates the rotation direction of the fixture when the thread 7 is in the right-hand screw direction.

Even if the thread 7 is in the left-hand direction, the cutting direction of the body hole 9 becomes the cutting angle a corresponding to the rotating direction when the fixture is placed. That is, even if the thread 7 is in the left-hand direction, the body hole 9 is formed so that the angle a between the tangent lines passing through the center line of the body hole 9 and the outer end of the body hole 9 becomes an acute angle, And penetrates from the outer peripheral surface of the fixture body 6 to the inner hole 8 in an inclined manner. When the thread 7 is formed in the left-hand direction and the fixture body 6 is turned in the left-hand screw direction, a bone piece generated when the thread 7 pushes or cuts the alveolar bone 4, Can be introduced into the inner hole (8) by riding on the inner wall (9).

The threaded cutout hole 11 also communicates from the outer peripheral surface of the fixture body 6 to the inner hole 8 so that the inner hole 8 and the threaded cutout hole 11 are connected to each other. 23 and 24, the thread cut-out portion hole 12 is also constituted by a hole inclined at a certain angle (a) toward the inner hole.

A cutting angle a is given when cutting the outer peripheral surface of the fixture body 6 where the thread cutting portion 11 is formed to form the thread cutting hole 12. The cutting direction of the screw cut-out portion hole 12 of the fixture body 6 is the cut-away direction corresponding to the rotational direction when the fixture is placed. Specifically, when the fixture body 6 is viewed in a flat section, the threaded cutout hole 12 is formed obliquely with respect to a tangent line passing through the outer end of the threaded cutout hole 12. The screw cut-out portion hole 12 is sloped from the outer circumferential surface of the fixture body 6 to the inner hole 8 such that the angle a between the center line of the screw cut-out portion hole 12 and the tangent line is an acute angle range. In the figure, the thread cut-out portion hole 12 is sloped when the thread 7 is in the right-hand screw direction. When the fixture body 6 is rotated in a right-hand direction, a bone piece generated when the thread 7 pushes or cuts and alters the alveolar bone 4 abuts on the inclined thread cut- Lt; / RTI >

Even when the thread 7 is in the left-hand direction, the cutting direction of the thread cutting hole 12 becomes the cutting angle a corresponding to the rotating direction at the time of fixture mounting. That is, even when the thread 7 is in the left-hand direction, the thread cut-out portion hole 12 is formed such that the angle a between the tangent lines passing through the center line of the thread cut-out portion hole 12 and the outer- (12) is sloped from the outer circumferential surface of the fixture body (6) where the thread cutting portion (11) is formed to the inner hole (8). When the thread 7 is in the left-hand direction and the fixture body 6 is rotated in the left-hand screw direction, the bone pieces generated when the thread 7 pushes or cuts the alveolar bone 4, Can enter the inner hole (8) by taking the hole (12).

The implant fixture according to the present invention having the above-described structure has an internal hole 8 and an internal thread 112, an internal ceiling concave-convex portion 114, a bottom surface convex-concave portion 116, (9) so as to further strengthen osseointegration between the alveolar bone (4) and the fixture.

In the present invention, an inner hole 8 is formed on the bottom surface of the fixture (that is, an inner hole 8 communicating from the lower end of the fixture body 6 to the inside thereof) ), And is provided with an internal thread 112, an internal ceiling concave-convex portion 114, and a bottom-surface concave-convex portion 116 to be connected to the internal hole 8 (the hole 8 in the bottom surface of the fixture) The alveolar bone 4 generated in the bottom hole 8 of the bottom of the fixture is connected to the alveolar bone 4 outside the fixture via the fixture body hole 9, ) To maintain the healthy state of the alveolar bone 4, shortening the period of the implant treatment, and widening the contact area between the alveolar bone 4 and the fixture, thereby further enhancing the osseointegration.

In addition, the bones formed in the inner hole 8 of the bottom face of the fixture and the inner surface of the fixture are combined by the internal thread 112, the internal ceiling concave-convex portion 114, the bottom concave-convex portion 116, So that a more robust implant placement state is maintained.

The total fusion area is maximized due to an increase in the fusion area between the internal thread 112 and the alveolar bone, an increase in the fusion area between the internal ceiling concave-convex part 114 and the alveolar bone, and an increase in the fusion area between the alveolar bone 116 and the alveolar bone Therefore, a very durable and highly reliable implant can be implanted. The internal ceiling concavo-convex 114, the internal thread 112, the screw thread outside the fixture body, and the uneven surface 116 of the bottom surface of the top surface, the inside surface, the outside surface, and the bottom surface, So that the fixture can be held in a state of being very firmly placed on the alveolar bone.

There is a case where the fixture having a length of 10 mm or more is hard to be placed due to the lack of alveolar bone or the anatomical structure such as maxillary sinus and hypochondria due to inflammation or the like. And a bottom surface concave portion 116. The internal thread 112 and the internal surface concave and convex portion 114 and the bottom surface concave and convex portion 116 provide the maximum total fusion area The fixture of the present invention, which has a large alveolar bone contact area and a large bone fusion area, has an advantage of being able to withstand a sufficient occlusal pressure even if a short length fixture is placed. Therefore, the meaning of the internal thread 112, the internal ceiling concave-convex portion 114, and the bottom-side concave-convex portion 116 is very significant.

In addition, in the present invention, the autogenous bone, which is formed by drilling a hole in the bone during drilling, is taken by a small surgical instrument and the autogenous bone is pushed into the hole 8 at the bottom of the fixture, A space can be filled with an autogenous bone and then a fixture can be placed. Alternatively, a drill and a trepin bar 16 can be used to form an alveolar bone in the shape of a fixture when the fixture is placed.

In the initial stage of drilling for positioning the fixture, drilling is performed with a general drill to a depth of about 1 to 7 mm to form a hole in the bone, and then, using the bottom surface irregular portion 116 provided on the bottom of the fixture, May be self-tapping to be placed.

It is also possible to fill the inner hole 8 of the bottom surface of the fixture with bone substitutes such as artificial bone and collagen. The autogenous bone, artificial bone, and collagen may be referred to as an alveolar bone formation promoting material 22.

When the implant 8 is filled with the alveolar bone formation promoting material 22 in the inner hole 8 of the fixture body 6 and the implant is implanted into the alveolar bone formation facilitating material 22, 4). Therefore, it is possible to further increase the bonding strength between the fixture of the present invention and the alveolar bone 4. Since the alveolar bone formation promoting material 22 is a substance that is friendly to the alveolar bone 4 of the implant recipient, it is possible to form a stronger support structure of the implant fixture without any foreign object. Since the inner hole 8 of the fixture body 6 is filled with the alveolar bone formation promoting material 22 so that the alveolar bone 4 is formed and filled in the inner hole 8, It is possible to shorten the period of the implant treatment. The period of filling the alveolar bone 4 with the inner hole 8 formed in the fixture body 6 is shortened while blood is smoothly supplied to the depth of the thread 7 of the outer circumferential surface of the fixture body 6 The alveolar bone formation promoting material 22 has a great significance in that the inflammation of the gum 2 is eradicated but synergistic effect is shortened to shorten the implant treatment period.

In the present invention, the fixture bottom hole 8, the internal thread 112, the internal ceiling concave-convex portion 114, the bottom surface concave-convex portion 116, the fixture body hole 9, the screw hole 10, The new alveolar bone 4 is formed and connected to the alveolar bone 4 between the upper and lower threads 7 so that the blood 3 is supplied to the alveolar bone 4 between the upper and lower threads 7. [ (4) enlarges the blood flow of the alveolar bone (4) and enlarges the contact area between the implant and the alveolar bone (4) by holding the fixture around the fixture as a net by the alveolar bone (4) ) To prevent damage, thereby eliminating failures such as implant dropout and shaking. The present invention is characterized in that the alveolar bone 4 is filled in the inner hole 8, the body hole 9, the threaded hole 10 and the thread cutting portion 11 so that the strong alveolar bone 4 is inserted into the fixture body 6 And a plurality of alveolar bones 4 are connected to the alveolar bone 4 outside the fixture body 6 such as a mesh network so that the fixture can be maintained in a state of being placed with a considerably strong supporting force on the alveolar bone 4 .

At this time, the inner hole 8, the fixture body hole 9, and the threaded hole 10 of the fixture are formed into a circular shape, an elliptical shape, a cylindrical shape, a tapered cylindrical shape, a polygonal shape such as a polygonal shape, And the like.

In this case, there is a difference in the area or volume to be contacted between the threaded hole 5 and the cut-out portion 8, so that the supply amount of the blood 3 can be more reliably increased. Further, the mesh of the alveolar bone 4 The same structure can be made stronger, so that it is possible to completely eliminate the failure of the alveolar bone (4) due to the occlusal pressure and periodontal inflammation, the failure of the implant, and the shaking. The shape of the alveolar bone 4 that holds the fixture body 6 and the thread 7 like a net can be varied so that the structure of the alveolar bone 4 that holds the fixture can be made more rigid, It is possible to completely eliminate the failure of the alveolar bone (4) due to pressure or periodontal inflammation, the failure of implant removal, and shaking.

Further, in the present invention, a threaded cutout portion hole 12 extending from the thread cutout portion 11 to the inner hole 8 is further formed. This thread cutting hole 12 is also filled with the alveolar bone 4 to be connected to the alveolar bone 4 filled in the inner hole 8 of the fixture body 6 and also to the alveolar bone 4 outside the fixture body 6 The strength of the support between the fixture body 6 and the alveolar bone 4 can be further increased by the alveolar bone 4 filled in the threaded cutout hole 12 and the blood supply amount can be further increased.

The body hole 9 and the thread cut hole 12 are formed by holes which are inclined at a certain angle a toward the inner hole 8 so that when the fixture body 6 is rotated, (Autogenous bone) that is generated when pushing or cutting the tooth 4 can be introduced into the inner hole 8 through the inclined body hole 9 and the inclined thread cutting hole 12, The resulting autogenous bone can be naturally generated by the support ribs in the fixture body 6, and the convenience can be enhanced when the autogenous bone is formed into the internal support ribs in the fixture. The cutting direction of the fixture body hole 9 and the threaded cutout hole 12 is given by a cutting angle a corresponding to the rotational direction when the fixture is placed so that the peripheral bones to be cut and compressed when the fixture is rotated are fixed to the fixture body hole 9 through the screw hole 12 and the hole 8 in the bottom face of the fixture to promote the formation of the alveolar bone 4 in the fixture inner hole 8.

A plurality of threaded holes 5 are formed in the thread 7 so that the alveolar bone 4 between the thread 7 and the alveolar bone 4 is connected to each other. A screw hole 5 penetrating the upper and lower surfaces of each thread 7 of each layer on the outer circumferential surface of the fixture body 6 is formed so that the fixture is placed in the alveolar bone 4, The alveolar bone 4 enters into the hole 5 and a bone connecting between the upper and lower threads 7 is created. The bone part connecting between the upper and lower threads 7 through the threaded hole 5 can be referred to as a connecting alveolar bone 4.

Therefore, the size and volume of the alveolar bone 4 contacted with the thread 7 by the alveolar bone 4 produced through the threaded hole 5 formed for each thread 7 on the outer circumferential surface of the fixture body 6 is increased The alveolar bone 4 is maintained in a healthy state and the alveolar bone 4 is held around the fixture as a net so that the alveolar bone 4 is prevented from being damaged due to occlusal pressure or periodontal inflammation Therefore, it is possible to eliminate failures such as implant dropout and shaking.

On the other hand, the threaded holes 5 are arranged in the zigzag direction along the vertical direction. The threaded hole 5 formed in the thread 7 of the lower layer relative to the threaded hole 5 formed in the thread 7 of the upper layer when the fixture body 6 is viewed from the side is displaced. The threaded hole 5 formed in the thread 7 of the upper layer and the threaded hole 5 formed in the thread 7 of the lower layer are disposed at positions displaced from each other with respect to the vertical direction of the fixture body 6 . Thus, the threaded holes 5 are arranged in the zigzag direction.

When the threaded holes 5 are vertically connected to each other in a row, the periodontal ligament 4 of the threaded hole 5 connected to the upper and lower rows in the upper and lower rows of the gingiva 2 causes the periodontal ligament to spread to the root of the root, There is room to be eliminated.

However, in the present invention, the threaded holes 5 are arranged between the upper and lower threaded portions 7 as described above, so that the alveolar bone 4 (bone) in the middle portion between the threaded holes 5 is robust, strong. In other words, the threaded holes 5 are arranged between the upper and lower threads 7 so that the threaded holes 5 are not connected to each other in the upper and lower rows in a row, but between the threaded holes 5 formed in the upper and lower threads 7, (2) is irritated because it is not a structure in which the periodontal ligament spreads to the tip of the root along the alveolar bone (4) of the threaded hole (5) The irritation does not easily spread vertically downward and downward, but inflammation is limited to only a part of the alveolar bone 4, so that there is no possibility that the fixture can be quickly removed due to periodontitis. As a result, . In other words, even if the periodontal salt tries to spread down through the threaded hole 5 formed in the upper thread 7, the lower thread 7 will shield the periodontal glands from spreading, It is not spread more, but is limited to the upper side. On the other hand, even if the periodontal salt tries to spread upward through the threaded hole 5 formed in the lower thread 7, since the upper thread 7 prevents the periodontitis from spreading, It does not spread more and is limited to the bottom.

On the other hand, the thread cutters 11 and 8 are preferably arranged so as to be displaced upward and downward when viewed from the side of the fixture body 6 in the zigzag direction.

The thread cut portion 11 formed on the thread 7 of the lower layer relative to the thread cut portion 11 formed on the thread 7 of the upper layer when the fixture body 6 is viewed from the side is disposed at a position shifted. The thread cutting portion 11 and the thread cutting portion 11 formed on the thread 7 of the upper layer and the thread cutting portion 11 formed on the thread 7 of the lower layer on the basis of the vertical direction of the fixture body 6 are displaced . Thus, the thread cutting portion 11 is arranged in the zigzag direction. This thread cutout 11 extends from the end of the thread 7 to the outer circumferential surface of the fixture body 6.

Therefore, even if the periodontal salt tries to spread down through the thread cuts 11 formed in the thread 7 of the upper layer, since the thread 7 of the lower layer prevents the periodontitis from spreading, And the upper thread 7 prevents the periodontal gland from spreading even when the periodontal gland tries to spread upward through the thread cutter 11 formed in the lower thread 7, , Inflammation does not spread more from below to upper, but only to the lower. It is also meaningful that the extended thread cutting portion 11 is also arranged in a zigzag shape so as to be shifted upward and downward.

It is to be understood that the terms "comprises", "comprising", or "having" as used in the foregoing description mean that a component can be implanted unless specifically stated to the contrary, But should be construed as further including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of 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 construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

1. Natural teeth 2. Gums
3. Blood 4. Alveolar bone
5. Crown 6. Fixture body
7. Thread 8. Inner hole
9. Body hole 10. Threaded hole
11. Thread cutout 12. Thread cutout hole
112. Internal threads 114. Internal ceiling concave-
116. Bottom surface concave-

Claims (9)

Fixture body;
A thread provided on an outer circumferential surface of the fixture body;
A bottom surface concave / convex portion provided on the bottom surface of the fixture body and configured to have a triangular shape, a wavy pattern, or a serrated shape and to cut a bone during an operation;
An inner hole provided inside the hole shaped by a predetermined height from the lower end to the upper end of the fixture body;
A thread cutting portion that communicates from the proximal end to the distal end of the screw body on the outer circumferential side of the fixture body and communicates from the upper surface to the lower surface of the screw;
A screw cutout hole provided in the fixture body so as to communicate with the inner hole from the base end of the thread cutout portion; And
And a body hole communicating with the inner hole from an outer peripheral surface of the fixture body,
Wherein a centerline of the body hole or the thread cutout hole has a slanting angle with respect to a tangent line which contacts an outer end of the body hole with a reference plane section of the fixture body. The method according to claim 1,
The body hole or the thread cut-out portion hole may be formed in the rotational direction when the fixture body is placed, so that the bone block generated by the thread can be introduced into the body hole or the thread cut-out portion hole when the fixture body is placed. Wherein the implant fixture is an inclined hole corresponding to the implant fixture. The method according to claim 1,
Wherein the thread has a plurality of threaded holes formed to pass from the upper surface to the lower surface of the thread,
Wherein said threads are comprised of N layers,
Wherein the threaded hole formed in the first layer of the Nth layer of the threads and the threaded hole formed in the second layer adjacent to the first cut of the thread and the thread cut portion are arranged in a zigzag direction, Thereby preventing the inflammation from spreading in the vertical direction of the fixture body. The method according to claim 1,
Wherein the bottom surface concave-convex portion self-taps the bottom of the primary perforation hole caused by drilling of the alveolar bone of the recipient to create an annular perforation hole. 5. The method of claim 4,
And the inner hole is coupled to the residual alveolar bone inside the annular perforation hole. delete delete delete delete

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