WO2016055531A1 - Implant structure - Google Patents

Abstract

The invention relates to an implant structure for fixing a dental prosthesis to the jaw, comprising an implant body which can be inserted into a jaw bone, said implant body comprising a recess, said implant structure also comprises an implant abutment (4) provided for receiving a dental prosthesis, said implant abutment having a front side (4b) via which it is inserted into the recess of the implant body, and anti-rotation means, first anti-rotation means being formed on the implant body and second anti-rotational means (24, 26) being embodied on the implant abutment (4). The first anti-rotating means comprises a row of projections and recesses which are arranged in an alternating manner, next to each other and are formed in the recess of the implant body. The second anti-rotation means comprises a row of recesses (26) and projections (24) which are complementary to the projections and recesses of the first anti-rotation means and which are arranged in an alternating manner next to each other and are arranged on the lower front side (46) of the implant abutment (4). The projections and the recesses of the first anti-rotational means are designed to directly engage with the recesses (26) of the second anti-rotational means and the projections (24) of the second anti-rotational means are designed to directly engage with the recesses of the first anti-rotational means.

Description

 implant structure

The invention relates to an implant structure for attaching dental prostheses to a jaw, with an implant body insertable into a jaw bone, which has a recess, a structure provided for receiving a dental prosthesis, which has a lower end face, with which it is to be arranged in the recess of the implant body , and rotation securing means, of which first anti-rotation means on the implant body and second anti-rotation means are formed on the structure.

An implant is an artificial material implanted in the body that is to remain there permanently or at least for a longer period of time. In human medicine, implants are used when a natural material such as teeth can no longer fulfill its function due to illness, wear or traumatic injury.

In the field of dentistry, to which the present invention relates, so-called dental implants are used in the jawbone, which take over the function of an artificial tooth root and are provided with a denture. Two-part implant structures, which are also referred to as implant systems, are used most frequently and can be inserted from the actual, into the jawbone Implant body and a structure, also referred to as the abutment and to which the dentures is attached, put together. To arrange the structure on the implant body of the implant body is provided with a recess which receives a lower portion of the structure. The interfaces between the implant body and the structure can be designed differently and include both conical connections with cone angles of in particular about 10 ° to about 50 ° and parallel-walled vertical and / or horizontal surface connections. In order to protect the set on the implant body structure against rotational forces, anti-rotation means are provided.

From DE 40 28 857 A1, an implant structure is known, in which at the distal, upper end of the implant body an annular recess is provided, which is provided with a contact shoulder for a retaining ring. The contact shoulder has four forehead indentations. An implant post provided as a construction has, in the manner of a shoulder, an annular shoulder pointing downwards toward the implant body, which is provided with a serrated, crown-shaped spur toothing and is arranged adjacent to an upper attachment head serving to receive the dental prosthesis. The arrangement of the implant post in the implant body by screwing, while the retaining ring, which consists of plastic, is increasingly compressed within the annular recess in the implant body. The end depressions on the abutment shoulder in the annular recess of the implant body on the one hand and the spur toothing on the annular shoulder of the implant post on the other hand each form form-fitting depressions, in which the plastic material of the retaining ring due to its viscoelastic properties when tightening the implant post more and more 'flows'. This creates a friction both between the implant body and the circlip on the one hand and between the structure and the circlip on the other hand, so that using the circlip a rotationally secure connection between the structure and the implant body is created. However, such a construction is relatively complicated, especially when unscrewing the structure of the implant body, the risk of destruction of the retaining ring, so when re-attachment the structure of the implant body, the use of a new retaining ring is required.

It is an object of the present invention to propose a simplified construction for an implant structure of the type mentioned, which is also particularly suitable for the use of modern materials such as preferably plastic.

This object is achieved according to the present invention with an implant structure for attachment of dental prostheses to a jaw, with an insertable into a jaw bone implant body having a recess, a provided for receiving a dental prosthesis construction having a lower end face, with which he the recess of the implant body is to be arranged, and rotational securing means, of which first anti-rotation means on the implant body and second anti-rotation means are formed on the structure, characterized in that the first anti-rotation means comprise a series of alternately adjacent projections and recesses and are formed in the recess of the implant body, the second anti-rotation means comprise a series of recesses and projections formed alternately adjacent and complementary to the projections and recesses of the first anti-rotation means, and to the lower stem are arranged side of the structure and the projections of the first rotation locking means for direct engagement with the recesses of the second anti-rotation means and the projections of the second anti-rotation means for direct engagement with the recesses of the first anti-rotation means are formed.

Characterized in that according to the invention formed in the recess of the implant body first anti-rotation means having a series of alternately adjacent projections and recesses and provided on the structure second anti-rotation means corresponding thereto complementary recesses and projections, a direct rotationally fixed engagement of the structure with its second anti-rotation means can be on the implant body with its first anti-rotation means on constructive simple and effective way to realize without the use of other security components or other components. A further simplification of the construction also contributes that according to the invention, the second anti-rotation means are arranged on the lower end side of the structure.

Furthermore, the invention takes into account the special requirements that are placed on the material of implant structures. Namely, if the implant consists of a material with high strength and only very little physical elasticity, the forces acting on the dental prosthesis or the prosthesis (supraconstruction) during chewing are transmitted via the structure directly into the implant body and from there to the jawbone , However, such a rigid structure does not correspond to the natural suspension of the tooth in the jaw, which is elastic, so there is a risk of the occurrence of the so-called "stress shielding" effect. By "stress shielding" is meant a reduction in bone density due to the absence of normal bone stress by an implant. Namely, it is known that the bone builds up under normal conditions and increases in strength. Thus, if the materials used for an implant are too stiff for the bone and therefore lack the stimulation necessary to maintain and adjust the bone, the bone in the area of the implant loses its mass and loses its density due to the shielding of the physiological stresses imposed by the implant Strength. Therefore, so-called high-performance plastics such as, in particular, polyetheretherketone (PEEK) have recently found their way into this field because they have a modulus of elasticity similar to that of the bony tissue, whereby the bone continues to be subjected to physiological stress so as not to lose stability. Therefore, these high-performance plastics and especially PEEK are increasingly used as a material for dental implants. However, due to the circumstances discussed above, it must be taken into account that these high-performance plastics have a certain flexibility due to their elasticity. With the present invention, however, the finding has been made that the construction according to the invention advantageously ensures that this property is at least essentially not noticeable. Accordingly, the construction according to the invention ensures even when using the mentioned high performance plastics a rotationally fixed connection between the structure and the implant body.

Preferred embodiments and further developments of the invention are specified in the dependent claims.

A preferred embodiment of the invention is characterized in that the projections protrude from the lower end face of the structure. This version offers not only a particularly effective anti-rotation device, but also a particularly space-saving design. In a development of this embodiment, in which the structure has an elongated shape, the projections are approximately in the longitudinal direction of the structure of the lower end face.

In a further preferred embodiment in which the implant body and the assembly each have an elongated shape, the row of projections and recesses is angled, preferably substantially transversely, to the longitudinal extent of the implant body and the assembly, thereby resulting in insertion of the assembly into the implant body in a simple and effective way a secure rotationally fixed engagement of the projections with the recesses can be achieved.

Preferably, the angle between the edge of the protrusions facing the row of protrusions and recesses and the bottom of the recesses is about 90 ° or greater than 90 °. With such an arrangement, the projections can be particularly simple and at the same time safely insert into the recesses.

In another preferred embodiment, the angle between the edge of the projections pointing in the direction of the row of projections and recesses and a tangent passing through the intersection between the edge and the outside of the projection is approximately 90 °. As a result, the opposing edges of two adjacent projections extend substantially transversely to the orientation of the row of projections and recesses and in particular in a curved row in the radial direction. Particularly useful for the realization of an effective anti-rotation is to give the row of the projections and recesses a curved course. It is particularly preferred that the series of projections and recesses forms a closed, preferably approximately circular, ring.

In a further development, the angular distance between each two adjacent projections and two adjacent recesses over the entire length of the row is substantially the same, which simplifies the orientation of the structure relative to the implant body in the direction of rotation.

The same applies to a preferred embodiment in which the protrusions and recesses have substantially the same width as the number of protrusions and recesses.

Preferably, the thickness of the projections and thus the depth of the recesses is at least 0.1 mm and / or the height of the projections relative to the bottom of the recesses at least 0.1 mm.

Preferably, three projections and three recesses are provided. Of course, but also a different number of recesses and projections is conceivable, with an even number of recesses and projections is appropriate.

Preferably, the structure has a pin-shaped lower end portion, at its free end, the lower end side is formed. This is the case, for example, if the structure is designed as an implant post. In this case, preferably the zapfenformige lower end portion of the structure and the recess in the implant body have a corresponding shape, which can be a flat connection between the structure and the implant body can be achieved. In a preferred development of this embodiment, the zapfenformige lower end portion of the structure has a conically tapered to the lower end face shape and the recess in the implant body a complementary and thus conically widening outward shape. A further preferred embodiment of the invention is characterized in that the implant body and / or the structure is made at least in sections and in particular in the region of the anti-rotation means made of plastic, from the group PEEK, PA, PE, POM, PMMA, PVAc, PU, PAEK, preferably PEEK or polymer blends thereof or based thereon, in particular carbon fiber reinforced PEEK, selected and preferably shaped or shaped by means of an injection molding process. For example, it is preferably conceivable to produce the construction from PEEK and the implant body from carbon fiber filled PEEK.

In this connection, it is additionally or alternatively conceivable to provide PEEK, in particular carbon-fiber-reinforced PEEK, which preferably contains endless carbon fibers, with a coating of biomaterial, such as, for example, hydroxylaptite, this measure forming an independent aspect of the invention.

Hereinafter, a preferred embodiment of the invention will be explained in more detail with reference to the accompanying figures. Show it:

1 shows the implant structure according to a preferred embodiment of the invention in an exploded, perspective, longitudinally sectioned representation (a) and in the assembled state in longitudinal section (b) and in side view (c); and

Figure 2 is an enlarged detail view of the lower end portion of the structure in perspective view (a), from the side (b) and from below (c).

First of all, it should be stated at this point that in the following description, the terms such as "top" designating an upper relative arrangement and position and the terms such as "bottom" designating a lower relative arrangement and position refer to the orientation of the components shown in FIG , From the perspective of the jaw, not shown in the figures, the terms indicating an upper relative arrangement and position such as "Up" for a distal orientation and the terms indicating a lower relative arrangement or position such as "down" for a proximal orientation.

FIG. 1 shows an implant structure according to a preferred exemplary embodiment of the invention. As can be seen from FIG. 1, the illustrated implant structure is substantially rod-shaped or post-shaped and has an implant body 2 and a structure 4. Alternatively, the implant body 2 may also be referred to as a base body and the structure 4 as an abutment or implant post. To fix the structure 4 on the implant body 2, a screw 6 is used. The implant body 2 can be inserted into a jawbone not shown in the figures. For this purpose, in the illustrated embodiment, a so-called implant sleeve 8 is used, which is fastened in a bore formed in the jawbone for this purpose. In this implant sleeve 8 of the implant body 2 is used, as shown in Figures 1 b and c. The structure 4 serves to receive a tooth replacement, not shown in the figures, which is placed on the structure 4 and secured thereto.

As can be seen in particular Figure 1 a, the implant body 2 at its upper end 2a an opening and is closed at its lower end 2b. In the opening at its upper end 2a opens a recess 2c, which is bounded by a circumferential inner wall 2d and a remote from its upper end bottom 2e. From the bottom 2e of the recess 2c, an internally threaded bore 10 extends in the direction of the closed lower end 2b of the implant body 2.

As can be seen in particular from FIG. 1 a, the upper end 8 a of the implant sleeve 8 has an opening and is closed at its lower end 8 b in the illustrated embodiment. The implant sleeve 8 contains a cavity 8c, which opens into the opening at the upper end 8a and is delimited by a circumferential inner wall 8d and the closed lower end 8b. The cavity 8c in the implant sleeve 8 serves to receive the implant body 2, as can be seen in particular FIG. 1b. For attachment in the jawbone implant sleeve 8 is on its outside with a thread Provided 12, so that the implant sleeve 8 can be screwed in the manner of a tapping screw into a corresponding hole in the jawbone. For anchoring the implant sleeve 8 in the jawbone are of course also alternatively or additionally other mounting options such as the use of adhesive conceivable.

As can be seen from FIGS. 1 a and b, projections 14 are formed on the inner wall 8d of the implant sleeve 8, which protrude into the cavity 8c. These projections 14 serve as fixing means for fixing the implant body 2 in the implant sleeve 8. For this purpose, the outer side 2f of the implant body 2 is provided with corresponding depressions 16 into which the projections 14 engage, as can be seen schematically in FIG. Preferably, the implant sleeve 8 is glued or welded to the implant body 2.

The implant body 2 and the implant sleeve 8 receiving this together form the so-called implant. Alternatively, it is also conceivable, for example, to form the implant body 2 in one piece together with the implant sleeve 8 surrounding it or to insert the implant body 2 shown in FIG. 1 directly into the jawbone without using the implant sleeve 8. Regardless of whether it is the implant body 2 and the implant sleeve 8 to separate parts to be joined together or a one-piece construction, at least in the arrangement in the jaw bone as a one-piece implant can be moved, which consistently consists of a material and has both an external and an internal thread.

As can be seen from FIGS. 1 a and b, the structure 4 is open at its upper end 4 a and at its opposite lower end 4 b and thus contains a cavity 4 c which passes through from the upper end 4 a to the lower end 4 b. The structure 4 is inserted with a lower portion 4d in the recess 2c of the structure 2, as can be seen in Figure 1b. In this case, the lower end 4b defining the lower section 4d forms a lower end face, which in the installed state lies opposite the bottom 2e of the recess 2c in the implant body 2. In the illustrated embodiments, the lower portion 4d of the structure 4 is a tapered to the lower end 4b, a substantially slightly conical shape and the inner wall 2d formed in the structure 2 complementary, so that in the mounted state, the lower portion 4d of the structure 4 with its outer side substantially flat at the Inner wall 2d in the structure 2 is applied, as shown schematically in Figure 1 b. Such a conical connection may have cone angles of up to about 50 °. Alternatively, parallel-walled vertical and / or horizontal surface connections are also conceivable.

For fixation of the structure 4 on the implant body 2, the screw 6 is provided, which has at its lower portion an external thread 18 which is formed complementary to the internal thread 10 in the implant body 2. The screw 6 is inserted through the cavity 4 c of the structure 4 and brought with its external thread 18 in screw engagement with the internal thread 10 in the implant body 2. In this case, the screw 6 comes with a formed below its head 6a, annular recess 6b in abutment against a formed on the inner wall 4e of the cavity 4c in the structure 4, annular shoulder 4f, whereby the screw 6 at a further movement through the structure 4 and the Implant body 2 is prevented and thus pulls the structure 4 with its lower portion 4 d in the recess 2 c in the implant body 2. As a result, the lower section 4d of the structure 4 is brought with its outer side into planar contact with the inner wall 2d of the recess 2c in the implant body 2.

With the help of the screw 6 is thus ensured that the structure 4 can not be detached from the implant body 2, but remains fixed to this. Due to the flat contact of the outer side of the lower portion 4d of the structure 4 on the inner wall 2d of the recess 2c of the implant body 2, although a certain frictional engagement between the structure 4 and the implant body 2 is formed. However, this frictional engagement is not strong enough to impact the implant body 2 set structure 4 to protect against rotational forces. Rather, for this purpose, a suitable rotation protection is required, the first anti-rotation means 20, 22 on the implant body 2 and second anti-rotation means 24, 26 comprises on the structure 4. Here are the first anti-rotation means 20, 22 and the second anti-rotation means 24, 26 are formed so that they engage in the arrangement of the structure 4 with its lower portion 4d in the recess 2c in the implant body 2 with each other. The first anti-rotation means comprise a series of alternately adjacent projections 20 and recesses 22, of which only one projection 20 and an adjacent recess 22 are shown recognizable in FIG. 1a. As can be further seen in FIG. 1 a, the projections 20 and recesses 22 are formed in the lower portion of the recess 2c bounded by the bottom 2e in the implant body 2 by arranging the projections 20 on the lower portion of the inner wall 2d and projecting from the bottom 2e of the recess 2c and thereby the recesses 22 formed between the projections 20 are limited in the radial direction outwardly from the inner wall 2d and in the axial direction downwards from the bottom 2e of the recess 2c.

The second anti-rotation means 24, 26 on the structure 4 also have a number of alternately adjacent projections 24 and recesses 26, of which in Figure 1 a only a projection 24 and a recess 26 are shown recognizable, while the figures 2a to c the training the in-line projections 24 and recesses 26 show completely. As can be seen in particular Figures 1 a and 2a and b, the projections 24 are arranged on the lower end forming the lower end 4b of the structure 4, from where the projections 24 protrude in the longitudinal direction of the structure 4, wherein between each two adjacent projections 24th in each case a recess 26 is formed in the same orientation.

As can be seen in particular Figures 2a and c, three projections 24 and three recesses 26 are provided in the illustrated embodiment, and the series of projections 24 and recesses 26 forms a closed circular ring which rotates in the circumferential direction and thus transversely to the longitudinal extent of the structure 4. However, for other embodiments, a different number of projections 24 and recesses 26 may be selected, with an even number of projections 24 and recesses 26 is appropriate. As can also be seen from FIG. 2 c in connection with FIG. 2 a, in the illustrated exemplary embodiment the width a, the dimensions of the row of projections 24 and recesses 26, of the recesses 26 are substantially equal to those of the row of projections 24 and recesses 26 Width z _{a of} the projections 24. Thus, in the illustrated embodiment, the width ratio between the projections 24 and the recesses 26 is substantially 1: 1, but may differ in other embodiments thereof.

In the illustrated embodiment, the angular distance between each two adjacent projections 24 and each two adjacent recesses 26 over the total length or the circumference of the row of projections 24 and the recesses 26 therefore substantially equal and is 60 °. Of course, it is also conceivable to choose a deviating angular distance, if a different number of projections 24 and recesses 26 is used by the illustrated embodiment, wherein it is expedient to keep the angular distance basically the same.

The outer wall 24a and the inner wall 24b of the projections 24 extend in the illustrated embodiment parallel to each other. Accordingly, the angle indicated in FIG. 2b is α = 0 °. Thus, the thickness or depth or the width b defined in the radial direction between the outer wall 24a and the inner wall 24b is the same over at least a substantial portion of the height h of the projections 24 defined in the axial direction, as shown in FIGS. 2a and 2b. However, in the illustrated embodiment, that portion of the outer wall 24a of the projections 24 is chamfered, which is adjacent to the free end 24c of the projections 24, wherein the free end 24c forms the end face of the projections 24. Alternatively, however, it is also conceivable to orient the outer wall 24a and the inner wall 24b of the projections 24 at an angle to one another in other embodiments, so that in such a case the angle α is> 0 °. The thickness b and the height h of the projections 24 are preferably at least 0.1 mm. As can be seen in FIG. 2b, in the illustrated embodiment the angle β between the radially oriented side wall 24d of the projections 24 and the bottom 26a of a respective adjacent recess 26 is 90 °. In this case, the side wall 24d forms a in the direction of the row of projections 24 and recesses 26 facing edge of the projections 24. In principle, it is also conceivable to choose in alternative embodiments, this angle ß greater than 90 °.

As can be further seen in Figure 2c, in the illustrated embodiment, the angle γ between the side wall 24d and a tangent passing through the intersection between the side wall 24d and the outside wall 24a of the projections 24 is 90 °. Alternatively, it is also conceivable to choose a different angle of 90 ° for other embodiments.

The above-described projections 24 and recesses 26 formed on the assembly 4 are provided for direct engagement with the recesses 22 and the projections 20 in the recess 2c of the implant body 2. For this purpose, in the illustrated embodiment, the projections 20 and the recesses 22 in the recess 2c of the implant body 2 are complementary to the recesses 26 and the projections 24 formed on the structure 4. Therefore, in the illustrated embodiment, the foregoing description of the design and dimensioning of the projections 24 and the recesses 26 applies mutatis mutandis to the projections 20 and the recesses 22 in the implant body. 2

For the preparation of the engagement of the projections 24 and the recesses 26 of the structure 4 with the recesses 22 and the projections 20 of the implant body 2 to achieve a rotation protection engages in each case a projection 24 of the structure 4 in a recess 22 of the implant body 2 and a projection 20 of the Implant body 2 in a recess 26 of the structure 4. For the case shown in the illustrated embodiment, that the lower portion 4d of the structure 4 has a tapered to the lower end 4b, has a substantially slightly conical shape and the inner wall 2d formed in the structure 2 correspondingly complementary is, whereby in the assembled state between see the outside of the lower portion 4d of the structure 4 and the inner wall 2d in the structure 2, a substantially flat cone connection is formed, the free end 24c of the projections 24 of the structure 4 ends above the bottom 2e of the recess 2c in the implant body 2 and the bottom 26a of Recesses 26 below the free end of the projections 20 in the implant body 2. In the case of a parallel-walled cylindrical connection, in which the lower portion 4d of the structure 4 and the inner wall 2d in the structure 2 each have a corresponding cylindrical shape, it is conceivable that free end 24c of the projections 24 of the assembly 4 in contact with the bottom 2e of the recess 2c in the implant body 2 and the bottom 26a of the recess 26 in contact with the free end of the projections 20 in the implant body 2 to bring.

The implant body 2 and / or the structure 4 are preferably at least partially and in particular in the field of anti-rotation means made of plastic, from the group PEEK, PA, PE, POM, PMMA, PVAc, PU, PAEK, preferably PEEK or polymer blends thereof or the base thereof, in particular carbon fiber reinforced PEEK, selected and preferably shaped or molded by means of an injection molding process. For example, it is preferably conceivable to produce the construction from PEEK and the implant body from carbon fiber filled PEEK.

Claims

claims 1 . Implant structure for fixing dentures to a jaw, having an implant body (2) which can be inserted into a jawbone and which has a recess (2c), a provided for receiving a dental prosthesis construction (4) having a lower end face (4b), with which it is to be arranged in the recess (2c) of the implant body (2), and  Anti-rotation means, of which first anti-rotation means (20, 22) on the implant body (2) and second anti-rotation means (24, 26) on the structure (4) are formed, characterized in that the first anti-rotation means comprise a series of alternating juxtaposed projections (20) and recesses (22) and formed in the recess (2c) of the implant body (2), the second anti-rotation means comprise a series of recesses (26) and projections (24) formed alternately adjacent and complementary to the projections (20) and recesses (22) of the first anti-rotation means and arranged on the lower face (4b) of the assembly (4) are and the protrusions (20) of the first anti-rotation means are adapted to engage directly with the recesses (26) of the second anti-rotation means and the protrusions (24) of the second anti-rotation means are directly engaged with the recesses (22) of the first anti-rotation means. 2. Implant structure according to claim 1, characterized in that the projections (24) protrude substantially from the lower end face (4b) of the structure (4). 3. implant structure according to claim 2, wherein the structure (4) has an elongated shape, characterized in that the projections (24) approximately in the longitudinal direction of the structure (4) from the lower end face (4b) protrude. 4. implant structure according to at least one of the preceding claims, wherein the implant body (2) and the structure (4) each have an elongated shape, characterized in that the series of projections (20; 24) and recesses (22; 26) is oriented at an angle, preferably substantially transversely, to the longitudinal extent of the implant body (2) and the structure (4). 5. implant structure according to at least one of the preceding claims, characterized in that the angle (ß) between the in the direction of the row of projections (24) and recesses (26) facing edge of the projections (24) and the bottom (26 a) of the recesses (26) is about 90 ° or greater than 90 °. 6. implant structure according to at least one of the preceding claims, characterized in that the angle (γ) between the in the direction of the row of projections (24) and recesses (26) facing edge (24d) of the projections (24) and one through the intersection between the edge (24d) and the outer side (24a) of the projection (24) running tangent is about 90 °. 7. Implant structure according to at least one of the preceding claims, characterized in that the row of projections (20; 24) and recesses (22; 26) is curved. An implant structure according to claim 7, characterized in that the angular distance between each two adjacent projections (20; 24) and each two adjacent recesses (22; 26) over the entire length of the row is substantially equal. 9. Implant structure according to claim 7 or 8, characterized in that the series of projections (20; 24) and recesses (22; 26) forms a closed, preferably approximately circular, ring. 10. implant structure according to at least one of the preceding claims, characterized in that the projections (24) and recesses (26) substantially the same in the row of the projections (24) and recesses (26) sized width (a, z _a ) to have. 1 1. Implant structure according to at least one of the preceding claims, characterized in that the thickness (b) of the projections (24) and the depth of the recesses (26) is at least 0.1 mm. 12. implant structure according to at least one of the preceding claims, characterized in that the height (h) of the projections (24) relative to the bottom (26 a) of the recesses (26) is at least 0.1 mm. 13. Implant structure according to at least one of the preceding claims, characterized in that three projections (20; 24) and three recesses (22; 26) are provided. 14. implant structure according to at least one of the preceding claims, wherein the structure (4) has a pin-shaped lower portion (4d), at its free end, the lower end face (4b) is formed. 15. An implant structure according to claim 14, wherein the peg-shaped lower portion (4d) of the structure (4) and the recess (2c) in the implant body (2) have a mutually corresponding shape. 16. An implant structure according to claim 14 or 15, wherein the lower portion (4d) of the structure (4) to the lower end face (4b) conically tapered shape and the recess (26) in the implant body (2) a complementary and thus after has conically widening shape on the outside. 17. implant structure according to at least one of the preceding claims, characterized in that the implant body (2) and / or the structure (4) at least partially, and in particular in the region of the anti-rotation means (20, 22, 24, 26) is made of plastic, the from the group PEEK, PA, PE, POM, PMMA, PVAc, PU, PAEK, preferably PEEK or polymer blends thereof or based thereon, in particular carbon fiber reinforced PEEK, and is preferably designed or shaped by means of an injection molding process.