KR100817642B1 - Implant - Google Patents

Abstract

The present invention relates to an implant. The present invention improves the conventional bone adhesion implant to minimize the drilling of the lower end of the implant to prevent overheating during drilling to prevent necrosis of the bone. The present invention allows the alveolar bone to be easily, safely and firmly implanted in the desired direction and position in any situation where it is very difficult to implant the implant.

The present invention relates to an implant having a structure to increase the success rate of the procedure and function faster and to help prevent the absorption of alveolar bone after implantation. The implant of the present invention is an implant that is sharply narrowed in a streamlined shape while going to the bottom while the shape of the implant is narrowed from top to bottom as a whole. The screw structure of the implant of the present invention has a shape in which the upper and lower portions or upper portions of the triangular threads are removed.

Artificial Teeth, Implants, Adhesions, Implants, Streamlined, Screwed, Protuberant, Core

Description

Implants {IMPLANT}

1 is a front view of an embodiment of the implant of the present invention.

2 is a cross-sectional view of an embodiment of the implant of the present invention.

3 is a detailed view of a thread of an embodiment of the implant of the present invention.

Figure 4 is a comparison of the support bone mass according to the screw form of the embodiment of the implant of the present invention.

Figure 5 is a comparison according to the number of threads of the embodiment of the implant of the present invention.

6 is a comparative view of an embodiment of the implant of the present invention.

Figure 7 is a diagram illustrating the implantation of the implant and the existing implant according to the present invention in a healthy bone.

8 is a diagram illustrating the implantation of the implant and the existing implant according to the present invention in the missing bone.

9 is an explanatory diagram comparing the difference in bone compressibility according to the type of implant.

It is explanatory drawing comparing the difference of the degree of loss of a bone after a meal.

11 is an explanatory view of the superstructure of the external implant according to the present invention.

12 is an explanatory diagram of a superstructure of an internal implant according to the present invention.

Figure 13 is an explanatory view of the superstructure of the one-body implant according to the present invention.

   The present invention relates to the appearance of osteoadhesive implants for artificial teeth. Since the invention of the bone adhesion implant in early 1960, the appearance of the implant has been modified so as to facilitate the surgical procedure while increasing the success rate of the bone adhesion of the implant.

   In the conventional implant form, the diameter of the implant site inserted into the alveolar bone was cylindrical with the upper part and the lower part almost coincident. Conventional cylindrical implants have a high contact area with the alveolar bone and a high bearing capacity, while a large amount of deletion at the lower end of the bone is high, the risk of overheating at the lower end is high, and the alveolar bone around the implant is likely to be necrotic. In addition, it is difficult to implant the implant by pump tapping, it takes a lot of time for drilling, and the hole is widened by repeated removal, which often leads to difficulty in obtaining sufficient initial fixation.

  In addition, the conventional external implant is showing a state that the alveolar bone is absorbed in a certain amount after being placed, which results in weakening the bearing capacity of the bone and exposing the implant to the outside. This is particularly bad when the implant is repaired in the anterior region. It was recognized that a certain physiological width is required for the external defense of the human body between the implant and the external connection. Therefore, there is an urgent need for new development of implants that can reduce the absorption of the actual alveolar bone while providing minimal physiological width.

A key part of today's improvement of dental fusion implants is the provision of implants that are easy to place and easily obtain the ideal initial fixation, furthermore providing fast and long-lasting implants with low bone resorption It is.

For easy implant placement, drilling of the alveolar bone must be easy. Easy drilling means less damage to the alveolar bone, less drilling process and less time spent. One type of implant that meets these requirements is a conical implant that is smaller in diameter from top to bottom than a conventional cylindrical shape. Conical implants have a small amount of bone removal at the bottom, and removal is not even at the tip of the drill, but evenly on all sides, reducing the risk of overheating and making it easier to change direction when drilling.

 However, conical implants have a weak penetrating force during insertion, so if more than a certain amount of dropout force is applied, the bone between the threads is easily destroyed and the implant easily turns away. If the implant is out of place during the placement, it is easy to fail and has a long wait even if successful. In addition, human alveolar bone does not have a constant bone quality, but the bone density varies depending on the depth, so when implants are placed in these places, the probability of the implant turning is higher.

Another problem is how to reduce the bone absorption of the upper end of the conventional implant. Two stage external implants, such as the Brenemmak implants, exhibit 1.5-2 mm of bone resorption at the interface between the top and top of the implant. The main cause of this is physiological pulsation. In order to protect the alveolar bone from external exposure, the presence of soft tissue between the alveolar bone and the outside is required and its minimum length is about 1.5 mm, which is called 'physiological width'. Therefore, it is possible to reduce the absorption of the alveolar bone if the structure of the upper implant can be clinically reduced physiological width. However, when the upper part of the implant is exposed without exposure to the alveolar bone or when inflammation occurs around the implant, the structure should not be a structure that spreads inflammation faster or promotes destruction of the alveolar bone than a conventional implant.

Therefore, the technical problem of the present invention is to provide an implant that is a conical implant and does not easily turn around even if the bone quality is weak and can easily dig into any case with minimal bone removal and to place the implant at a desired depth and obtain a firm initial fixation. In addition, the present invention changes the upper structure of the implant to increase the area where the gum binds to the implant even in a short length to secure the physiological width, consequently reducing the bone absorption inevitably occurring in the upper part of the implant, and yet the implant is alveolar bone Even if exposed outside, it provides a periodontal healthy implant.

   The present invention relates to an implant. The present invention is composed of an implant portion that is inserted into the alveolar bone narrows as it goes to the bottom, the lower end has a streamlined shape of the pointed to meet, the upper end has one or more circular or screw-shaped grooves or protrusions It is characterized by.

In the present invention, the upper part of the implant comes down with the same diameter as the core or both the outer diameter of the screw, the middle portion of the implant can have a shape in which both the core and the outer diameter of the implant is narrowed to 5-10 degrees. have. In addition, the present invention can be configured to have a shape in which both the outer diameter of the core and the core or the core portion of the implant portion narrows 5-10 degrees.

 In the present invention, both the external shape of the thread and the central core of the implant at the lower end of the implant may have a shape that meets each other by sharply narrowing the ends of the implant as a whole in a curved line. In addition, the present invention can be configured to have a shape in which both the external shape of the thread and the central core of the implant in the lower end of the implant narrowed to a straight conical shape as a whole, the end pointed to meet, the core of the pointed end of the lower end of the implant The diameter starts from 0-1.5mm and widens to the top, and a screw of 0-0.5mm depth can be started from the lower core around it so that the thread can be clearly formed at the top.

* The present invention can form a gum joint at a portion where the spiral portion that meets the upper connection portion of the implant. The gum coupling portion may form one or more circular or threaded grooves or protrusions. In the present invention, it is possible to form a surface enlargement portion formed of an inclined surface on the lower portion of the gum engaging portion and the upper portion of the spiral portion. The surface enlargement portion may have a plurality of spiral grooves or protrusions.

 The present invention discloses a new type of implant which is configured to improve the conventional implant, to be easily, safely and firmly placed in the alveolar bone, to function more quickly, and to help prevent the absorption of the alveolar bone after implantation.

Hereinafter will be described an embodiment of the present invention based on the drawings.

1 and 2 are front and cross-sectional views of an embodiment of the invention implant.

Implant 100 of the embodiment of the present invention is composed of a connecting portion 140 and the spiral portion 110 is connected to the artificial tooth, gum connection having a groove or protrusion between the connecting portion 140 and the spiral portion 110 The part 130 may be formed under the connection part. In addition, in the present invention, the surface enlargement portion 120 may be configured as an inclined surface between the lower portion of the gum coupling portion 130 and the spiral portion. The surface enlargement portion may have a plurality of spiral grooves or protrusions.

Spiral portion 110 of the implant 100 of the present invention has a shape that narrows down the diameter below the middle portion of the spiral portion while going to the lower end sharply narrowed to the streamlined shape like the proximal end of the tooth do.

That is, the spiral part has a cylindrical shape with a certain diameter down, and has a gentle slope from the middle part to the bottom part, and the diameter becomes narrower and becomes narrower sharply toward the lower part, and has a streamlined tip like a proximal end of the tooth. It is done.

The features of the implant relate to the body part that enters the alveolar bone, as well as in a two-stage internal implant and a one-stage internal implant, or an integral one-body. body) It can be applied to any implant system, regardless of the shape of the superstructure, such as the implant.

The cylindrical portion of the spiral portion of the implant of the present invention is a portion that plays the most resistance to the force that the implant is to fall off during implant placement, the middle portion of the spiral portion having a gentle inclined portion serves to facilitate implant drilling and implantation The lower end of the spiral portion, which is the biggest feature of the implant of the present invention, minimizes alveolar bone deletion and plays a role of successfully implanting the implant at a desired position and depth safely in any alveolar bone situation.

3 is a detailed view of a thread of an embodiment of the implant of the present invention.

3A is an explanatory diagram of an embodiment in which the upper 20 and lower portions 22 of the equilateral triangular thread are removed to form a long, thin and pointed tip. This thread is characterized in that it is formed deep to the bottom of the implant.

Figure 3b is an embodiment of the form of the conventional triangular threads horizontally divided by the upper half 24 is completely removed and the lower portion is removed a portion 26.

The upper and lower thicknesses 28 of the parallel portions of the screws in FIGS. 3A and 3B may ideally be in the range of 0.2-0.3 mm but in the range of 0.1-0.6 mm, and the implant body (hereinafter 'core') 30 The angle 34 formed by the upper surface 32 of the screw is ideally 70-90 degrees, but may range from 60-110 degrees. The angle 38 formed by the core and the lower surface 36 of the screw may vary from 90 degrees. It can have -120 degrees. The angle 42 of the pointed threaded end 40 of the screw is suitable for 30 degrees but may range from 10-60 degrees. The horizontal length 44 of the screw is suitable for 0.4mm but may have a length of 0.3-0.8mmm and the thread spacing 46 may be in the range of 0.3-1.0mm although 0.6-0.8mm is suitable.

Figure 3c is an embodiment of the form having a shape that removes only the upper portion 48 of the conventional triangular screw and the lower portion 50 without removing the lower triangle.

This type also has a structure that overcomes the disadvantages of the insertion of the conical implant as mentioned above, but the force to withstand the vertical load is smaller than Figure 3a or 3b.

The upper triangular screw (20, 24, 48) of the screw shape is removed form the structure designed to favor the force of the implant to fall off when the implant is mainly inserted and the lower triangular screw (22, 26) removed form is the implant It is a structure that can tolerate vertical occlusal force more effectively than triangular screw structure at the time of implantation.

The screw shape of Figure 3a or 3b is to remove the top and bottom of the equilateral triangular screw to make the thickness 28 of the screw thin and long, which can maximize the bone volume between the threads while maintaining the same spacing between the threads. In addition to increasing the bone contact area, the screw was thinned to minimize the rotational insertion required for self-tapping. Here, self-tapping is a method of inserting an implant without forming a thread in the bone in advance so that the bone is cut by the implant thread. Also, due to the parallel surface of the lower part 36, the load applied to the bone by the implant during the function can be always applied vertically, which is advantageous for early functioning.

 In addition, the purpose of designing all the ends of the screw is to make the self-tapping more advantageous than the square screw of the right angle. This is because the screw structure can increase the initial fixation force while effectively penetrating the alveolar bone with the insertion rotation force smaller than the square screw when the implant is inserted by self-tapping. Square screws have excellent strength to withstand vertical pressure, but there is a high possibility of facing the situation where the implant stops in the middle due to over-rotating load when inserted by self-tapping. Therefore, square screws often require the pre-tapping method of pre-tapping the thread before inserting the implant, which increases the drilling time and increases the chance of loosening the implant.

In conclusion, the screw structure increases the amount of bone between the threads and increases the bone contact area with the implant without increasing the spacing of the threads, while self-tapping can be effectively achieved without excessive rotational insertion during implantation. As a structure that withstands lateral force as well as the occlusal pressure, the structure is invented to reduce the probability of falling or falling off during implant placement, and to secure an initial fixation to provide an implant that can function early.

Figure 4 is a comparison of the support bone mass according to the screw form of the embodiment of the implant of the present invention.

It is explanatory drawing explaining the support bone amount of the conventional cylindrical implant.

It is explanatory drawing explaining the support bone mass of the conventional conical implant.

4C is an explanatory diagram illustrating the support bone mass of an implant of the present invention.

In general, a conical implant with a triangular screw has a smaller amount of bone (52,54) that resists the force to fall out compared to a cylindrical implant with a triangular screw, and even the direction of the force acting on the bone is lateral. It is weak, so if you don't put enough pressure on the implant, it will turn out easily.

However, the shape of the screw is a structure that overcomes the weakness of the conical implant that narrows toward the bottom like the implant. As shown in Fig. 4-c, the amount of bones (56, 58) resisting the force of the implant to be removed by removing the upper half of the triangular screw in the form of a straight or concave curve while having a right angle or an acute angle 34 from the core surface. And the direction of the force acting on the bone is at least vertical or directed towards the implant core to allow the bone between the threads to resist sufficient tensile force, significantly reducing the appearance of insertion that is common in conical implants. It can easily penetrate easily into the holes formed in it, get the desired initial fixation and freely return it to the planned depth without stopping in the middle.

Figure 5 is a comparison according to the number of threads of the embodiment of the implant of the present invention.

Figure 5a is an embodiment adopting a single row screw in the embodiment of the implant of the present invention.

Figure 5b is an embodiment employing two-threaded screw in the embodiment of the implant of the present invention.

Figure 5c is an embodiment adopting a three-screw screw in the embodiment of the implant of the present invention.

Various implant threads of the present invention can be applied in the form of two- or three-row screws to double the insertion speed and increase the initial fixation force as well as single-row screws.

6 is a comparative explanatory view for explaining the form of the lower end thread of the implant of the present invention.

6A is an explanatory view for explaining the structure of the thread of the lower end portion in the embodiment of the implant of the present invention.

It is explanatory drawing explaining the structure of the screw thread of the lower end part of the conventional implant.

Fig. 6C is an explanatory diagram for explaining the structure of the thread of the lower end portion of the conventional implant of another embodiment.

The shape of the lower end of the implant of the present invention is sharply narrowed to the streamline 54 from the bottom of the remaining three to five threads from the bottom end of the implant (56) ends in a pointed shape and the thread is sharply similar size to the bottom of the implant Formed 58 is characterized. The lower end of the streamlined shape also means an outer shape 60 including a thread, but in another sense, the core shape 62 excluding the thread also narrows sharply at the same ratio as the outer shape.

The lower end of the conventional implant is flat (64) as the shape of the end cut as shown in Figure 6b or slightly convex (66) as shown in Figure 6c.

Also, from about 3-5 threads, the thread gradually disappears and the diameter becomes narrow (68, 70). The flat and wide end of this tip and poor thread formation at the bottom mean that the diameter of the core at the bottom of the implant is not narrowed. When the conventional implant is placed, drilling is performed according to the diameter of the core up to the bottom of the implant. There was a difficulty to do.

The need to form a wide hole down to the bottom poses a number of clinical risks. The wider the lower the diameter, the greater the risk of damaging adjacent roots or nerves, and the strong bones at the bottom are not easily drilled, easily overheated and necrosed, and the upper weak bones do not need to be drilled to widen the strong bones at the bottom. This can lead to many side effects, including widening more than necessary, resulting in weakening the initial fixation of the implant. On the contrary, when the lower end of the hole is formed small, the conventional implant can no longer penetrate due to the flat cross section and is easily caught by being caught in the middle.

The core shape of the lower end of the implant of the present invention is formed in a shape similar to the shape of the pointed tip and drilled with a twist drill having a diameter of 2 mm as shown in Figure 6a so that the diameter 56 of the tip of the core is about 0.3 mm Starting from (0.1-1.5mm), it can be configured to have a curved shape that becomes wider like a streamline at the top. A thread structure 58 of about 0.5 mm (0.1-0.7 mm) deep can be formed around the core at the bottom of the implant to the end of the implant core. Eventually, the entire diameter 72 of the lower end of the implant starts at about 0.8 mm (0.2-2.2 mm) and is about 3 mm at the 2 mm core site and is characterized in that it continues to widen upward to a certain length.

Figure 7 is a diagram illustrating the implantation of the implant and the existing implant according to the present invention in a healthy bone.

When deleting the alveolar bone for the end pointed implant, such as the implant of the present invention while continuing to widen the hatched portion (76), such as when placing a conventional cylindrical implant in the step-by-step deletion from a small drill to a large drill No need to delete In other words, the bottom of the implant only needs to be drilled once with the 2 mm drill, the first drill for implant drilling.

This is a very important part of goal elimination. Deleting bone on the upper side is not difficult and can be modified and drilled according to the judgment of the operator. The problem is how much less bone can be removed from the lower part of the implant as described above. The implant can be quickly and easily and simply drilled when implanting a long implant or drilling any bone such as a high density alveolar bone or a low density alveolar bone because of the advantage that the alveolar bone at the bottom of the implant can be minimized. In addition, even when the adjacent teeth are close or the lower alveolar nerve is close, the risk can be safely drilled with minimum risk.

The implants invented above only form holes with a core width and the implant is inserted into the threaded portion when the implant is inserted into the alveolar bone. The implant is streamlined at the bottom of the implant, the tip is pointed, and the screw structure is clearly alive until the end of the implant can be easily dug even if the hole is small or no. If it is not a very hard alveolar bone, most of the alveolar bone can be self-tapping without being pre-tapping.

Since the implant has a streamlined structure at the lower end and the screw structure, a strong initial fixation can be obtained even at the end of the implant, and thus a strong initial fixation can be obtained even at a short implant or a weak bone.

* Figure 8 is a diagram explaining the implantation of the implant and the existing implant according to the present invention in the missing bone.

As shown in FIG. 8, even when the bone is severely broken and the only end of the implant is inserted into the bone, the initial fixation is excellent and may well play a role in increasing the success rate of the implant by resisting lateral force. This advantage can be said to be a feature of the present invention that is difficult to expect from conventional implants that have flat ends or faint threads.

In particular, the implant is an implant structure that can securely secure the initial fixation at the weak bone, such as the maxillary posterior teeth. In areas with weak bones, it is difficult to obtain sufficient initial fixation, and thus the success rate is very low.

9 is an explanatory diagram comparing the difference in bone compressibility according to the type of implant.

The posterior part of the maxilla is weak in bone quality, so if the hole is made large, the implant easily loosens and is likely to fail. Therefore, the weaker the bone, the smaller the hole should be formed and the method of digging with only the implant should be applied. The difficulty of applying the conventional implant method is that the flat end is flat or thick and the thread is not well formed to the bottom. When the alveolar bone could not be pushed to the side and pushed downwards, even the power to penetrate was weak and eventually turned out in the middle.

Using the implant, however, it is possible to easily and simply obtain a strong initial fixation in any case while compressing the alveolar bone sideways by simply forming a small hole in the alveolar bone with weak bone quality and then pushing the large diameter implant to the side. . This is because the implant is sharply formed at the bottom of the implant and the screw structure is excellent in the effect of digging therein and has a streamlined structure that is excellent in compressing the alveolar bone laterally.

The implant is also very advantageous for obtaining a strong initial fixation in the dense bone of the lower maxillary sinus. Usually, the maxillary posterior alveolar bone is weak in bone and the lower maxillary sinus is composed of dense hard bone. If a conventional implant is placed in this area, a wide hole must be formed to penetrate the lower margin of the maxillary sinus, in which case it is difficult to obtain initial fixation at the weak bone and only a weak initial fixation at the lower margin of the maxillary sinus. If a small hole is inserted after insertion, the weak bone may dig, but the lower end of the implant will be caught in the lower maxillary sinus, and it will not be able to dig out.

The implant of the present invention does not need to widen the weak alveolar bone to form a wide hole in the lower maxillary sinus even in the above case. If only a small hole is formed to the lower margin and then pushed in, it can dig powerfully along the small hole of the hard maxillary lower margin and obtain an excellent initial fixation in both weak and hard maxillary sinus.

It is explanatory drawing comparing the difference of the degree of loss of a bone after a meal.

Another feature of the present invention is that there is one or more circular or threaded grooves or protrusions at the upper end of the implant where the upper connection of the external implant and the implant meet.

11 is an explanatory view of the superstructure of the two-stage internal implant according to the present invention.

This is another embodiment of the present invention, which is a two stage internal implant of the implant with one or more threaded grooves or projections in the upper surface augment.

12 is an explanatory view of the superstructure of the one-stage internal implant according to the present invention.

This is another embodiment of the implant of the present invention as a one stage internal (one stage internal) implant is one or more threaded grooves or projections in the upper surface enlargement.

Figure 13 is an explanatory view of the superstructure of the one-body implant according to the present invention.

FIG. 13 shows one or more circular or threaded grooves or protrusions at a site where the one body implant meets the gum, which is an externally exposed portion of the alveolar bone in the one body implant. The circular or threaded grooves or protrusions make the area that the gums bind to the implant even at shorter lengths at the site where the upper end of the implant meets the gum, thereby securing a physiological width at a shorter length than a conventional implant, resulting in an implant. It has the effect of reducing the absorption of alveolar bone at the top.

The implants have a smaller diameter from top to bottom as a whole, and especially the bottom ends are streamlined and pointed, so that when drilling inside the alveolar bone, it is very easy but more accurate and error-free drilling in the shortest time, and the alveolar bone is overheated and necrotic. The effect is that very few drilling methods can be applied.

The structure of the alveolar bone varies, so that some parts are dense and very difficult to drill and are easily overheated, and some parts are very weak and easily drilled, but are easily broken, and holes are formed too wide to weaken the fixation of the implant. Also, if the hole is made too narrow, the implant may enter and stop, in which case the implant or alveolar bone may be broken and may be in a difficult situation.

The formation of an ideal hole will provide the initial fixation of the desired implant, and the initial fixation is the first gateway to increase the success rate of the implant. However, alveolar bone has various bone densities depending on depth and area, so it is not difficult to form an ideal hole. The implant is an implant that can easily form an ideal implant hole with minimal bone removal in any alveolar bone situation.

The second effect of the present invention is that the implant provides an implant that is safely secured to the desired depth while obtaining a predictable ideal initial fixation upon implant placement. The implant prevents looseness at the time of implantation and is placed very tightly than the conventional implant by always eliminating hole deletion by a drill. And it is an implant that is securely dug into the strong alveolar bone due to the structure of the thread even if caught on the hard alveolar bone removed less during placement.

How wide the implant hole is usually formed is subject to the subjective judgment of the operator, but if it is misjudged, it is common to be too loose, too loose, or too narrow to be in the middle. However, the implant is an implant that reduces the error caused by the misjudgment of the operator as well as the satisfactory implantation result without being greatly influenced by the operator even if the operator drilled incorrectly.

The third effect of the present invention is that the implant is an implant that does not easily lie in the alveolar bone despite the streamlined structure. When the implant is inserted, the implant often no longer fits in the middle and is often overlaid. When the alveolar bone is turned too weak or meets a dense bone in the middle or deeper than the formed hole depth, the alveolar bone in the thread breaks and turns out. Implants that are narrower in diameter toward the bottom are more apparent than implants of the same diameter. If you turn away, there is a high probability that the implant will fail. The implant is an implant that does not turn out in any case where the alveolar bone meets a weak or dense bone or tries to insert it deeper even though the implant is a narrower implant.

The implant also provides an implant that minimizes bone resorption at the top of the implant. To this end, the present invention provides a physiological pedometer at a small distance by giving a fine thread or groove to the upper junction where the gum and implant meet so that the upper part of the implant fuses well with the soft tissue in the oral cavity to serve as a perfect sealing. By minimizing bone resorption inevitably occurs.

Claims (11)

delete In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and pointed at the lower end thereof, and at least one circular or screw-shaped groove or protrusion is formed at the upper end of the spiral portion, and the upper portion of the implant is cored. The screw outer diameter is all down to the same diameter by a certain portion, the middle portion of the implant is characterized in that both the core and the outer diameter of the screw has a shape that narrows the diameter 5-10 degrees. In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and pointed at its lower end, and has one or more circular or threaded grooves or protrusions formed on the upper end of the spiral portion, and the upper portion of the implant portion The core or the outer diameter of the middle portion of the implant all have a shape that narrows the diameter of 5-10 degrees. In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and pointed at the lower end thereof, and at least one circular or screw-shaped groove or protrusion is formed at the upper end of the spiral portion, and the outer shape of the spiral portion of the implant is formed. Implants, characterized in that both the core and the core of the implant is sharply narrowed by the curve of the mammary gland as a whole has a pointed end to meet each other. In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and the lower portion is pointed to meet, and at least one circular or screw-shaped groove or protrusion is formed on the upper portion of the spiral portion, and the lower portion of the spiral portion of the implant Implants, characterized in that both the outer shape and the central core of the implant has a shape that is narrowed in a straight conical shape as a whole and pointed ends. The method according to claim 4 or 5, The core diameter of the pointed end of the lower end of the implant's thread starts from 0.1-1.5mm and widens to the top, and a screw with a depth of 0.1-0.7mm starts around the core from the lower core to form a sharp thread. Implant, characterized in that. In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and pointed at its lower end, and at least one circular or threaded groove or protrusion is formed at the upper end of the spiral portion, and the screw structure of the implant is An implant, characterized in that it is configured to have a long, thin, pointed screw shape by removing the upper and lower portions of the equilateral triangle with a straight line or a curve horizontally around the upper and lower centers. In dental osteoadhesive implants, The spiral portion of the implant inserted into the alveolar bone has a streamlined shape that is narrowed toward the bottom and pointed at its lower end, and at least one circular or threaded groove or protrusion is formed at the upper end of the spiral portion, and the screw structure of the implant is The upper surface of the screw is removed by cutting a half of straight triangular thread into a straight or concave curve horizontally to remove the upper side, and the lower surface of the screw is configured to maintain the lower surface of the triangular screw as it is or to have a concave or convex curved surface. Implant, characterized in that. The method according to claim 7 or 8, The value of the implant screw is 60-110 degrees between the core and the top surface of the screw, the angle between the core of the implant and the bottom surface of the screw is 90-120 degrees, and the top and bottom thickness of the screw is 0.1-0.6mm. , The angle of the end of the thread is 10-60 degrees, the horizontal length from the core to the end of the screw is 0.3-0.8mm, the spacing of the thread is 0.3-1.0mm, characterized in that the implant. The method according to claim 7 or 8, Implant, characterized in that the screw structure consists of a single row or two or three rows of screws. The method according to any one of claims 2,3,4,5,7,8, The implant is provided with a connecting portion at the top of the spiral portion, a gum coupling portion is disposed between the connecting portion and the spiral portion, the gum coupling portion is an implant, characterized in that one or more circular or spiral grooves or protrusions formed on the outer surface .

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