JP7465620B2 - Self-tapping implant fixture - Google Patents

Description

The present invention relates to an implant fixture used in dental implant treatment.

Dental implant treatment is a type of dental treatment that is used to replace missing teeth caused by caries, periodontal disease, or trauma.

Typically, the main procedure for dental implant treatment involves using an implant drill to create a hole in the jawbone that is approximately the same as or slightly smaller than the outer diameter of the dental implant, and then hammering or screwing the dental implant into the drilled hole to embed the dental implant in the desired jawbone position.

There are two types of dental implant treatment methods: after the dental implant is placed, the gums are sutured to prevent the dental implant from being exposed in the oral cavity, and if the dental implant is an implant fixture with a spiral thread formed on its outer surface to facilitate insertion into the jawbone and to fix it to the jawbone immediately after placement, a healing period is allowed until new bone forms in the gap between the thread groove and the drill hole and fixation is achieved, and a prosthesis (dental crown) is attached after the healing period; and a one-stage treatment in which the implanted dental implant is exposed and the gums around it are sutured.

As for the specifications of dental implants, the one-piece type is the easiest to perform and has the advantage in terms of physical strength. As for the treatment method, one-stage treatment, in which the entire treatment is completed by attaching the prosthesis in the occlusal area that serves as the superstructure immediately after implanting the dental implant, is advantageous in that it can shorten the total treatment time and number of days, and can reduce the financial and mental burden on the surgeon and patient. However, cases in which one-piece types and one-stage treatment can be applied require that the jawbone has sufficient bone quality and bone mass, oral hygiene is good, and the treatment area is in a location and with teeth that are not subject to high occlusal pressure, and other intraoral conditions are met. Therefore, the current situation is that the specifications of the dental implant and the treatment method are appropriately selected according to the case.

In addition, implant fixtures used for dental implants come in a variety of types, including straight types with a roughly constant outer diameter from the tip to the back end, and tapered types where the outer diameter increases from the tip to the back end. In cases such as anterior teeth, where aesthetics after implant treatment are particularly important, the implant fixture is inserted and the insertion depth is fine-tuned according to its position relative to the surrounding bone, so the shape of the implant fixture is also selected appropriately to suit the case, such as by selecting a straight type that makes it easy to adjust the insertion depth.

Implant fixtures that have spiral threads on their outer surface are widely used to facilitate insertion into the jawbone and to ensure fixation with the jawbone immediately after implantation.

In recent years, technological developments have been made in dental implants to make them easier to use, and products with improved surface properties and shapes have been brought to the market, but each has its own advantages and disadvantages.

Patent Document 1 discloses an implant fixture with a self-tapping groove at the tip that is inserted into the jawbone, and it is known that providing a self-tapping groove can reduce the torque applied to the implant during self-tapping.

Patent Document 2 discloses an implant fixture with multiple threads, and it is known that the use of multiple threads can shorten the surgical time required for implantation.

Patent Publication No. 03307950 JP 8-501962 A

In implant treatment, when embedding an implant fixture, the position, depth and angle for embedding the implant fixture are planned based on information on the patient's jawbone and its surroundings that has been diagnosed in advance, and drill holes are formed according to the plan, and the implant fixture is embedded. Embedding an implant fixture is a task that is performed in the very limited field of view of the patient's oral cavity, and it is difficult to embed the implant fixture accurately in the position designed at the time of diagnosis.
The drill hole can be made smaller in diameter than the outer diameter of the implant fixture, and the implant fixture can be rotated and self-tapped to improve fixation immediately after implantation. However, because the implant fixture is attached to a tool that is held and operated with the fingers during implantation, the reaction force that the implant fixture receives from the jawbone during self-tapping can cause the implant fixture to wobble, and the implant fixture may be implanted at an angle that does not follow the drill hole.
To prepare for such cases, there has been a demand for an implant fixture that has high drilling ability at the time of implantation, high fixation to the bone immediately after implantation, and can be implanted at a desired angle along a pre-formed drill hole.

The present invention is a dental implant fixture having an implant portion to be implanted in a jawbone, the implant portion to be implanted in the jawbone has a truncated cone portion having a truncated cone shape and a cylindrical portion having an approximately cylindrical shape, the truncated cone portion and the cylindrical portion of the implant portion are connected along the central axial direction of the implant fixture, and have n self-tapping grooves from the truncated cone portion to the vicinity of the connection portion with the cylindrical portion, the cylindrical portion and the truncated cone portion have n x m continuous thread grooves, each of the thread grooves has the same lead and pitch, n is an integer of 3 or more, and m is a natural number.

It is preferable that the length between the valley of any thread groove in the cylindrical portion and the central axis of the implant fixture gradually increases from the frustum side of the cylindrical portion to the other end side. In addition, the outer diameter of the cylindrical portion having the thread groove may be constant, or the outer diameter of the cylindrical portion having the thread groove may be tapered, gradually increasing from the frustum side to the other end side of the cylindrical portion.

The dental implant fixture of the present invention preferably has a twist angle of the self-tapping groove of 1 to 60°, a leading flank angle of the threads of all thread grooves of 2 to 20°, and a trailing flank angle of 40 to 60°.

In addition, it is preferable that the other end of the cylindrical portion of the implantation part has a cylindrical cuff portion coaxial with the cylindrical portion or a groove that continues in the circumferential direction, and the other end of the cylindrical portion may further have a multiple thread groove that has the same lead as the thread groove and a smaller pitch than the thread groove.

It has high perforation properties when implanted, has high fixation to the bone immediately after implantation, and can be implanted at a desired angle along the pre-formed drill hole.

FIG. 1 is a side view of a preferred embodiment of an implant fixture of the present invention. FIG. 2 is a bottom view of the implant fixture shown in FIG. 1 . FIG. 2 is a partially enlarged side view of the implant fixture shown in FIG. 1 . 2 is a cross-sectional view of a plane including the axis of the cylindrical portion of the implant fixture shown in FIG. 1 . 2 is an enlarged partial cross-sectional view of a plane including the axis of the cylindrical portion of the implant fixture shown in FIG. 1 . FIG. 2 is a side view of one preferred embodiment of the implant fixture of the present invention. FIG. 2 is a side view of one preferred embodiment of the implant fixture of the present invention. FIG. 2 is a side view of one preferred embodiment of the implant fixture of the present invention. 1 is a partial cross-sectional view of a plane including a central axis of one preferred embodiment of an implant fixture of the present invention. 1 is a partial cross-sectional view of a plane including a central axis of one preferred embodiment of an implant fixture of the present invention.

The following describes preferred embodiments. However, the following embodiments are merely examples, and the present invention is not limited to the following embodiments. In addition, the present invention may include any other components.

The present invention is a dental implant fixture, and can be used for a dental implant having an implant fixture. As a first specification of the dental implant, it can be used for a one-piece type in which an implant fixture and an abutment are integrated. As a second specification of the dental implant, there is a two-piece type that is composed of two parts, an implant fixture that serves as a replacement site for a tooth root, and an abutment that serves as a replacement site for a crown abutment, and is used by connecting the abutment to the implant fixture. As a third specification of the dental implant, there is a three-piece type that is composed of three parts, an implant fixture, an abutment, and a screw, and the abutment is fixed to the implant fixture using the screw.
It can be used for any one to three piece types of dental implants of the first to third specifications.
The dental implant consisting of an abutment integrated with a dental implant fixture is a one-piece type dental implant of the first specification.
The dental implant, which is composed of a dental implant fixture and a separate abutment, is a two- or three-piece type dental implant of the second or third specification.

There are no particular limitations on the uses of the implant fixture of the present invention. For example, it may be the above-mentioned dental implant used to replace a missing tooth, or it may be a temporary implant used as a fixing point for orthodontic wires, or it may be a dental implant used for any other purpose.

Whether used for a one-piece type dental implant of the first specification for one-stage procedure, or for a two- or three-piece type dental implant of the second or third specification for two-stage procedure, the implant fixture can be implanted at a pre-planned angle, allowing for safe and secure treatment, which is a preferred embodiment of the present invention.
The dental implant fixture of the present invention has a diameter (thickness) of 3.0 to 5.0 mm, a length of 6.0 to 17.0 mm, a thread lead of 0.6 to 6.4 mm, and a pitch of 0.2 to 1.6 mm.
The diameter (thickness) of a dental implant fixture means the outer diameter of the cylindrical portion, and the length means the length of the embedded portion that does not include the abutment portion in the case of a one-piece type, and means the length of the embedded portion that is part of one piece including the cylindrical portion and the truncated cone portion in the case of a two- or three-piece type.

The dental implant fixture of the present invention is an implant fixture used in the oral cavity, and has an implant part to be implanted in the jawbone. The implant part of the dental implant fixture is a part to be implanted in the jawbone, and is preferably a part having a thread groove. Depending on the surgical procedure or use, the implant part may be embedded in the jawbone beyond the thread groove, but it is preferable that the implant fixture is embedded in the jawbone up to the end.
The embedding part has a truncated cone part and a cylindrical part that is approximately cylindrical. The wider of the upper and lower bases of the truncated cone is the lower base, and the lower base of the truncated cone and the bottom side of the cylinder are configured as a continuous, integrated shape.
The frustoconical portion of the implant fixture of the present invention is preferably in the shape of a tapered frustocone, but may have a variety of shapes, such as a dome shape.

A thread groove having a lead and a pitch is provided from the truncated cone portion to the cylindrical portion. The portion from the truncated cone portion to the cylindrical portion having the thread groove having the lead and pitch preferably forms an embedded portion. The truncated cone portion to the other end of the cylindrical portion preferably has a thread groove having a lead and a pitch, and is an embedded portion. The truncated cone portion preferably has a thread groove having a lead and a pitch from the top of the truncated cone portion.
The thread grooves in the implantation portion preferably have the same lead and pitch, and preferably always have the same lead and pitch in any portion. By having the same lead and pitch of the thread grooves, the implantation can be performed without damaging the jawbone.

The self-tapping groove of the dental implant fixture of the present invention is a groove formed vertically across the thread groove from the truncated cone portion of the dental implant fixture, which has a truncated cone shape, to near the junction with the cylindrical portion, and the cross-section of the thread formed by the thread groove on the outer periphery of the implant fixture cut by the self-tapping groove functions as a cutting blade, forming a female thread in the jawbone and allowing the implant fixture to screw forward while screwing into it.
In order to accurately implant the implant fixture at the desired angle, it is desirable that when the implant fixture is inserted into the drill hole, the cutting edges of the cross-section of the thread formed by the thread groove simultaneously contact multiple points and multiple positions that are axially symmetrical with respect to the central axis of the implant fixture, thereby starting to screw into the jawbone.
If there is only one point where screwing starts, the implant fixture will be pulled by the screwing force on the side where screwing starts, and the implant fixture will tilt to the side where screwing starts. Even if there are two points symmetrical to the axis of the cylindrical part, the implant fixture will tilt in the perpendicular direction about the axis of the two points. The number of the self-tapping grooves is preferably three or more.

Furthermore, in order for the cutting blades formed by the cross section of the threads formed by the thread grooves to simultaneously begin contacting multiple locations and at positions that are axially symmetrical with respect to the central axis of the implant fixture, it is preferable that the thread grooves of the implant fixture are multiple thread grooves that have the same lead and pitch but different phases, that the thread grooves are preferably arranged at equal intervals around the axis of the cylindrical portion, and that the number of thread grooves is the same as the number of self-tapping grooves or multiple thread grooves that are a natural number multiple.

When the diameter of the implant fixture is small, the fewer the self-tapping grooves, the better, in terms of the mechanical strength of the implant fixture. Increasing the number of thread grooves on the implant fixture will inevitably result in a longer lead, making it difficult to control the implantation depth, so it is preferable to have the minimum number of grooves necessary. In other words, the number of self-tapping grooves is preferably three, which is the minimum necessary to ensure stability during implantation, and it is preferable for the implant fixture to have three thread grooves that have the same lead and pitch but are evenly spaced around the axis of the cylindrical part with different phases.

It is preferable that the length between the valley of any thread groove in the cylindrical portion and the central axis of the implant fixture gradually increases from the truncated cone portion side of the cylindrical portion to the other end side.
The length between the valley of any thread groove in a cylindrical portion and the central axis of the implant fixture means the distance of a straight line perpendicular to the axis of the cylindrical portion from the bottom of the valley of the thread groove to the central axis of the implant fixture on a plane including the axis of the cylindrical portion of the dental implant fixture.
The implant fixture of the present invention preferably has a gradually increasing shape in which the length between the valley of any thread groove in the cylindrical portion and the central axis of the implant fixture gradually increases. Gradual increase refers to a gradually increasing valley diameter. The gradually increasing state is a state in which the valley of the thread groove becomes smaller as the thread groove advances from the truncated cone portion side to the other end side. It is preferable that the gradual increase in the length between the valley of the thread groove and the central axis of the implant fixture increases at a constant rate. The gradually increasing shape does not need to be constituted by the entire thread groove, and may be a part of the thread groove.

The thread groove extends from the truncated cone portion to the other end of the cylindrical portion, but the portion in which the length between the valley of the thread groove and the central axis of the implant fixture gradually increases is at least in the cylindrical portion, and may be formed from the middle of the cylindrical portion, and preferably ends in the middle of the cylindrical portion. In addition, the portion in which the gradually increasing shape is formed is preferably formed from the transition part of the cylindrical portion on the truncated cone portion side toward the other end of the cylindrical portion. The portion in which the gradually increasing shape is formed preferably ends near the other end of the cylindrical portion from the truncated cone portion direction, and preferably ends at a position 0.7 mm or more away from the other end.

By having a shape in which the length between the valley of the thread groove and the central axis of the implant fixture gradually increases, the conical truncated portion of the dental implant fixture and its vicinity can have a deep thread groove, so that the drilling ability during implantation is not impaired, and the other end side of the cylindrical portion can have a shallow thread groove, so that fixation can be obtained immediately after implantation.

The outer diameter of the cylindrical portion having the thread groove of the dental implant fixture of the present invention is preferably constant. The term "constant" means that a straight line connecting the outer diameters is parallel to the axis of the cylindrical portion on a plane including the axis of the cylindrical portion.
The outer diameter of the cylindrical portion of the dental implant fixture of the present invention is preferably a curved surface that is equidistant from the axis that forms the center of the cylindrical portion in the vertical direction. The curved surface is parallel to the axis that forms the center of the cylindrical portion. By adopting this configuration, the embedding depth of the implant fixture can be finely adjusted during treatment.
In the dental implant fixture of the present invention, in a plane parallel to the axis of the cylindrical portion, it is preferable that a straight line constituting the outer diameter of the cylindrical portion is parallel to the axis in every plane.

The outer diameter of the cylindrical portion having the thread groove of the dental implant fixture of the present invention can be tapered, gradually increasing from the truncated cone portion to the other end of the cylindrical portion. It is preferable that the outer diameter increases at a constant rate, but it is not necessary for the entire thread groove to have a tapered shape that gradually increases, and only a part of the cylindrical portion can do. This configuration allows the tip of the implant fixture to be thinned without compromising mechanical strength, which is useful when selecting an implant fixture that matches the condition of the jawbone.

The twist angle of the self-tapping groove is preferably 1 to 60°. The twist angle of the self-tapping groove is the inclination of the self-tapping groove, with the angle parallel to the axis forming the center of the cylindrical portion being 0° and the angle parallel to the thread groove being a positive angle.
If the twist angle of the self-tapping groove is a positive value, the lower side of the cross section of the thread formed by the thread groove on the outer periphery of the implant fixture cut by the self-tapping groove will have an acute angle, so that the implant fixture can be screwed into the jawbone with a smaller rotational force, and the force that the implant fixture receives from the jawbone during self-tapping is reduced and stable. The twist angle is preferably 1 to 60°, and more preferably 25 to 50°.

The depth of the thread groove, which has a gradually increasing shape, is 0.15 to 0.4 mm at the transition between the cylindrical portion and the conical frustum portion, and 0.1 to 0.35 mm at the other end. The depth of the thread groove is measured perpendicular to the axis of the cylindrical portion of the implant fixture.

It is preferable that the leading flank angle of the thread of all thread grooves is 2 to 20°, and the trailing flank angle is 40 to 60°. More preferably, the leading flank angle is 2 to 10°, and the trailing flank angle is 45 to 60°. This angle is the angle formed with the perpendicular to the axis of the cylindrical portion. The leading flank angle is the angle formed by the inclination toward the truncated cone portion of the thread formed by the adjacent thread grooves and the perpendicular to the axis of the cylindrical portion. The trailing flank angle is the angle formed by the inclination toward the other end of the cylindrical portion of the thread formed by the adjacent thread grooves and the perpendicular to the axis of the cylindrical portion. Both the leading flank angle and the trailing flank angle are acute angles. The angle difference between the leading flank angle and the trailing flank angle is preferably 35 to 55°. It is also preferable that the sum of the angles of the leading flank angle and the trailing flank angle is 45 to 70°.

The other end of the cylindrical portion of the implantation part preferably has a circumferentially continuous groove, which is preferably circular and does not intersect with the thread groove.
The groove is formed around the entire circumference of the cylindrical portion, and one or more grooves are sufficient, and it is more preferable to form two or three concentric grooves. The depth of the groove is preferably 0.03 to 0.1 mm.
After the implant fixture is embedded in the jawbone, bacteria in the oral cavity that may invade the gap between the jawbone and the implant fixture can be stopped by the circular groove, preventing the bacteria from invading the thread groove.

It is preferable that the implant fixture has a cuff portion at the other end of the cylindrical portion, the cuff portion being coaxial with the cylindrical portion, in which case the circular groove is preferably located between the cuff portion (7) which penetrates the gingiva and contacts the gingiva and the cylindrical portion having the thread groove.
The outer surface of the cuff portion (7) does not need to be a rough surface as described above, and any known surface property can be appropriately selected and used. For example, a smooth surface or a mirror surface is preferable. The shape of the cuff portion (7) is also not particularly limited, but it is preferably a cylindrical shape with the same diameter as the cylindrical portion, and more preferably has an inverse tapered shape of 0.5 to 7°. A reverse tapered shape is a shape that becomes thinner as it approaches the end.
The length of the cuff can be selected within the range of 0.1 to 3.0 mm, preferably 0.3 to 1.5 mm.

The other end of the cylindrical portion may further have a multiple thread groove having the same lead as the thread groove of the cylindrical portion and a smaller pitch than the thread groove. In this case, the portion having the thread groove having a smaller pitch than the cylindrical portion may have any length in the central axis direction of the implant fixture. When the other end of the cylindrical portion of the implant fixture has the circular groove or the cuff portion, it is preferable that the portion having the thread groove having a smaller pitch than the cylindrical portion is located between the circular groove or the cuff portion and the cylindrical portion.

The dental implant fixture of the present invention shown in the drawings will now be described.
Fig. 1 shows a three-piece type implant fixture (1) of the present invention. Fig. 2 shows a bottom view of the implant fixture shown in Fig. 1. Fig. 3 shows a partially enlarged view of the truncated cone portion (2) of the implant fixture shown in Fig. 1. Fig. 4 shows a cross-sectional view of a plane including the axis of the cylindrical portion (3) of the implant fixture shown in Fig. 1. A structure (6) for connecting an abutment is provided from the other end of the cylindrical portion (3) to the inside of the implant fixture. Fig. 5 shows a partially enlarged view of the transition portion of the cylindrical portion (3) to the truncated cone portion (2) in the cross-sectional view shown in Fig. 4.
The implant fixture (1) in FIG. 1 has an implant portion to be implanted in the jawbone. The implant portion to be implanted in the jawbone is composed of a truncated cone portion (2), a cylindrical portion (3) having an approximately cylindrical shape at the bottom of the truncated cone portion, three thread grooves (4) having the same lead and pitch but different phases from the truncated cone portion to the other end of the cylindrical portion, and three thread tap grooves (5).
The implant fixture in Fig. 1 has a thickness of 4 mm, a length of 11 mm, a lead of 1.8 mm, a pitch of 0.6 mm, and a twist angle of the thread tap groove of 40°. Furthermore, the upper base of the truncated cone portion forms a flat surface.
The thread groove is configured to become shallower from the transition portion of the cylindrical portion to the truncated cone portion toward the other end.

The implant fixture (1) of the present invention can be one that has an internal mechanism (6) that supports a dental prosthesis, as shown in Figure 4, or one that has the mechanism externally, as shown in Figure 6.

The implant fixture of the present invention may also have a circumferentially continuous concentric groove (8) near the other end, as shown in Figure 6. In many cases after dental implant placement, it has been confirmed that bone resorption (retraction) of about 1 mm occurs from the jawbone surface toward the inside. One of the causes of this bone resorption is known to be bacteria invading the boundary with the dental implant from the jawbone surface side, causing the jawbone to erode. The concentric groove (8) is effective in preventing bacteria that cause bone resorption from invading the thread portion.

The concentric groove (8) is located between the other end of the cylindrical portion (3) and the end of the thread groove (4), and may be formed as a recess on the outer periphery of the implant fixture, or may be formed as multiple threads formed with minute protrusions, but it is sufficient to provide at least one groove on the outer periphery of the implant fixture.

The flank angle of the thread formed by the thread groove (4) can be 30°, the same as that of a general screw, but the drilling ability can be further improved by selecting an optimal flank angle. When the implant fixture is screwed into a drill hole that is drilled small at the time of implantation, a reaction force (104) of the force that spreads the surrounding bone is applied to the thread of the implant fixture as shown in FIG. 9. If the component force (107) received by the rear end surface of the thread is greater than the component force (105) received by the tip side surface of the thread due to the reaction force (104), the implant fixture will receive a downward force from the bone and will be more likely to screw in. In other words, the rear end flank angle (103) of the thread formed by the thread groove should be greater than the tip flank angle (102). In consideration of the depth, lead, and pitch of the thread groove that are preferable for the implant fixture, the tip flank angle (102) is preferably 2 to 20°, and the rear flank angle (103) is preferably 40 to 60°.

The material of the implant fixture (1) is not particularly limited, and any material known in the art can be appropriately selected and used as the material for implant fixtures. Examples include metal materials such as pure titanium and Ti-6Al-4V alloy, and ceramic materials such as alumina and zirconia.

The manufacturing method of the implant fixture (1) is not particularly limited, and a known manufacturing method used for manufacturing implant fixtures can be appropriately selected. The outer surface of the implant fixture (1) can be manufactured, for example, by cutting. The surface properties manufactured by simply performing cutting (CAM) using a general precision machining program (CAD) usually have an arithmetic mean surface roughness Ra of about 0.2 μm or a ten-point mean roughness Rz of about 2.0 μm, and this surface roughness value depends only on the machining marks. Such surface properties are not suitable for osseointegration with the jawbone. Even if the value of Ra or Rz is large, if the difference in height of the surface unevenness is simply large, it is not suitable for cell macrophages (proliferation), and it is difficult to obtain early osseointegration.

Therefore, the surface of the implant fixture that is embedded in the jawbone must be appropriately rough in order to achieve good osseointegration. Specifically, it is more preferable that Ra is 1.15 to 4.05 μm and Rz is 5.0 to 40 μm.

There are no particular limitations on the surface treatment method used to obtain such a surface, and any known surface treatment method can be appropriately selected and used. Examples of such methods include electric discharge machining, sandblasting, acid treatment, alkali treatment, anodizing, hydroxyapatite spraying, titanium spraying, and coating treatments such as calcium phosphate.

(Implant fixture placement experiment)
The implant fixture, which was machined from a titanium cylinder and surface-treated, was embedded in a rectangular parallelepiped mock bone for the implantation experiment. The drill hole had a diameter of φ3.2 mm and was drilled vertically from the top surface of the mock bone. After embedding, the angle between the vertical direction of the mock bone and the axis of the cylinder of the implant fixture was measured. The experiment was performed by the same tester, and the average value of the results of three experiments was used.

(Preparation of Samples)
Example 1: Sample A) An implant fixture of the present invention having a truncated cone section formed on a titanium cylinder 4 mm in thickness and 11 mm in length, with three thread grooves with a lead of 1.8 mm and a pitch of 0.6 mm extending from the truncated cone section to the other end of the cylinder section, and three thread tap grooves with a twist angle of 40° extending from the truncated cone section to the vicinity of the junction with the cylinder section.
Example 2: Sample B) An implant fixture of the present invention having the same shape as the previous example, with six thread grooves having a lead of 2.4 mm and a pitch of 0.4 mm, and with three thread tap grooves.
Example 3: Sample C) An implant fixture of the present invention having the same shape as the previous example, with four thread grooves having a lead of 1.6 mm and a pitch of 0.4 mm, and with four thread tap grooves.
Comparative Example 1: Sample D) An implant fixture having the same shape as the above-mentioned example, with two thread grooves having a lead of 1.2 mm and a pitch of 0.6 mm, and with two thread tap grooves.
Comparative Example 2: Sample E) An implant fixture having the same shape as the above-mentioned example, with three thread grooves having a lead of 1.8 mm and a pitch of 0.6 mm, and with two thread tap grooves.
Comparative Example 3: Sample F) An implant fixture having the same shape as the above-mentioned example, with two thread grooves having a lead of 1.2 mm and a pitch of 0.6 mm, and with three thread tap grooves.

(Results of implant fixture placement experiment)
As shown in Table 1, it was confirmed that the angles of the cylindrical axes of the implant fixtures of Samples A, B, and C, which are examples of the present invention, are significantly smaller than those of the comparative examples of Samples D, E, and F. It was shown that the implant fixture of the present invention can be implanted at a desired angle along the formed drill hole.

The dental implant of the present invention can be widely applied regardless of the condition of the jawbone and the oral environment, and meets the requirements of dental implants for both one-stage and two-stage procedures, making it possible to accommodate a variety of cases, while having high perforation properties when implanted, having high fixation to the bone immediately after implantation, and being useful because it can be implanted at a desired angle along a pre-formed drill hole. Therefore, the present invention can be widely used in the field of dental implants.

1 Implant fixture 2 Conical truncated portion 3 Cylinder portion 4 Thread groove 5 Self-tapping groove 6 Mechanical portion supporting dental prosthesis 7 Cuff portion 8 Concentric groove 9 Length between the valley of the thread groove and the central axis of the implant fixture 100 Twist angle of the self-tapping groove 101 Inclination angle of the thread groove 102 Front flank angle 103 Rear flank angle 104 Reaction force received by the implant fixture 105, 106 Component force received by the front surface of the thread 107, 108 Component force received by the rear surface of the thread

Claims (11)

A dental implant fixture having an implant portion to be implanted in a jawbone,
The implant portion to be implanted in the jawbone has a truncated cone portion having a truncated cone shape and a cylindrical portion having a substantially cylindrical shape, and the truncated cone portion and the cylindrical portion of the implant portion are connected along a central axis direction of the implant fixture,
n self-tapping grooves are provided from the truncated cone portion to the vicinity of the connecting portion with the cylindrical portion,
The cylindrical portion and the truncated cone portion have continuous n x m thread grooves,
The lead of the thread groove is the same for each row ,
The pitch of the thread groove is the same for each row,
1. A dental implant fixture, wherein n is an integer of 3 or more, and m is a natural number. 2. The dental implant fixture of claim 1, wherein n is 3. 2. The dental implant fixture according to claim 1, wherein the length between the valley of any thread groove in the cylindrical portion and the central axis of the implant fixture gradually increases from the truncated cone portion side of the cylindrical portion to the other end side. 2. The dental implant fixture according to claim 1, wherein the outer diameter of the cylindrical portion having the thread groove is constant. 2. The dental implant fixture according to claim 1, wherein the outer diameter of the cylindrical portion having the thread groove is tapered so as to gradually increase from the truncated cone portion side to the other end side of the cylindrical portion. 2. The dental implant fixture according to claim 1, wherein the twist angle of the self -tapping groove is 1 to 60 degrees. The dental implant fixture according to claim 1, characterized in that the leading flank angle of the threads of all thread grooves is 2 to 20° and the trailing flank angle is 40 to 60°. 2. The dental implant fixture according to claim 1, further comprising a cylindrical cuff portion at the other end of the cylindrical portion of the implantation portion, the cuff portion being coaxial with the cylindrical portion. 2. The dental implant fixture according to claim 1, wherein the other end of the cylindrical portion of the embedding portion has a groove that is continuous in the circumferential direction. 2. The dental implant fixture according to claim 1, further comprising a multiple thread groove on the other end side of the cylindrical portion, the multiple thread groove having the same lead as the thread groove and a smaller pitch than the thread groove. A dental implant comprising an abutment integral with or separate from any one of the dental implant fixtures according to claims 1 to 9.