DE202006010431U1 - Two part dental implant for replacement of lost tooth, has sealing body provided for sealing surfaces of distal and proximal implant parts and made from elastic, biocompatible and sterilizable material, where body has two sealing surfaces - Google Patents

Abstract

The implant has a distal implant part with a distal end (14) and a proximal implant part with a V-shaped projection (16). A sealing body is provided between surfaces of the distal implant part and the proximal implant part, where the sealing body has sealing surfaces facing the surfaces of the parts. The sealing body is made from an elastic, biocompatible and sterilizable material and seals the surfaces of the implant parts. Stop surfaces are provided between the implant parts, where the surfaces of the parts are run transverse to a longitudinal axis of the dental implant.

Description

The The invention relates to a two-part dental implant. A distal one Implant part is as artificial tooth root for the Implantation formed in a jawbone and a proximal Implant part carries an artificial one Tooth crown.

The The invention particularly relates to the connection between distal and proximal implant part, hereinafter also with implant-abutment connection designated and abbreviated to IAV. The proximal end of the distal implant part and the distal end of the proximal implant part are geometrically matching each other designed and border each other in the implanted state of the shaft at.

Dental implants serve the replacement of lost teeth. For dental implants differs one-and two-part systems. The present invention relates a two-part system. Such two-part systems have a distal and a proximal implant part. The distal Implant part is introduced into the jawbone and grows there with the bone. The proximal implant part - also called abutment - protrudes a few millimeters in the mouth and serves as an artificial tooth stump. In the present case, the distal implant part forms an artificial one Tooth root, during the proximal implant part forms the aforementioned artificial tooth stump. The proximal implant part takes dentures of various shapes, for example in the form of a crown and connects these over the distal implant part with the jaw.

Of the The distal implant part and the proximal implant part usually become in the longitudinal direction one in the longitudinal direction extending screw connected to each other. The geometry of the connection area between the distal implant part and the proximal implant part such that the connection between both implant parts is shaped or non-positively or both.

The main requirements for the connection between distal implant part and proximal implant part are: the connection must be stable, because they have enormous chewing forces is exposed. The fitting parts must be very precise and allowed to work in the assembled State have no column. The structure should be released from the implant at any time and again can be connected to it. Of the Construction should be able to be replaced by other structures. The Both implant parts must in the connected state rigid and backlash-free and against twisting around the implant longitudinal axis be assured. This is of particular importance when in one Pine multiple implants were inserted and these individual Implants a complex coherent construction, such as to take a screwed fixed implant bridge. Only with a precise rotation can be such implant construction be accurately manufactured. If multiple implant abutments be directly connected, for example in the case of a Bridge substructure, which is usually a removable denture wearing, can be dispensed with a rotation backup. To those for this Application provided web abutments is one of the already listed requirements further requirement posed: Bar abutments must allow the possibility that several interconnected abutments easily on the implants can be placed and connected to these, if the implant fixations, as usual, not parallel to each other in the bone were introduced.

Known two-part dental implants do not meet the aforementioned requirements to the desired extent. A particular problem with many known two-part implants is the transition between the two implant parts. Known deletion proposals eg from EP 0 842 643 . US 5,919,043 . EP 1 371 342 or US 6 152 737 are not satisfactory.

task it is, an improved in relation to the above requirements, Two-piece dental implant to create.

According to the invention this Task solved by a two-part dental implant, in which between proximal Implant part and distal implant part one with the help of a sealing body formed seal is provided, which is the opposite surfaces of the the proximal and distal parts of the implant so that no Germs and bacteria can invade.

Preferably have the distal and the proximal implant part facing each other stop surfaces on, which collide with fully assembled dental implant. These facing stop surfaces limit the measure of approach of the two facing surfaces of the implant parts, between those of the sealing body is arranged, and thus the maximum compression of the sealing body by the stop surfaces a minimum distance of the two facing surfaces of the Define implant parts. In this way, it is ensured that axial forces acting on the implant, e.g. Chewing forces, not from the sealing body but over the facing abutment surfaces are transmitted.

In a preferred variant of the Dichtkör pers has these sealing surfaces of elastic material, so that the sealing surfaces sealingly applied to designated surfaces of distal and proximal implant part when the distal and the proximal implant part are joined together. Seal and proximal and distal implant part are designed so that after making the final connection between the distal and proximal implant part a surface pressure between the sealing surfaces of the sealing body and the corresponding surfaces of the two implant parts prevails, which is maintained even when the implant is exposed to chewing forces and as a result of these chewing forces elastically deformed in the region of the transition from the proximal to the distal implant part.

Consequently is according to the invention between two at fully assembled, in longitudinal direction split shaft opposite each other and in relation to the radial direction of the shaft outer end surfaces sealing body provided as a seal which is dimensioned so that it at axial Loading of the dental implant not axial direction of the shaft is compressed and always compressed by lateral load at lateral load. The seal is thus merely when assembling the implant around the necessary measure like that compresses that implant-abutment connection under all potential circumstances ensures a tightness. The measure of Compression is dependent the material and the thickness of the material when using a greater height of the seal could the compression option the material will be smaller around the movements in the sealing area to compensate.

The experiment explained in more detail below shows that seals with a sealing body made of rigid material can not guarantee the desired tightness:
An examined implant was rigidly clamped in a holding device up to the height of the implant shoulder (proximal end of the distal implant part).

On the distal implant part was the proximal implant part by means of Screwed and a defined mounting force.

It was a force of 100N at 90 ° to the angle longitudinal axis of the implant on the proximal end face of the proximal implant part introduced and thereby an elastic (reversible) material deformation the joined together Implant components provoked.

This resulted in the following measurement results:
In the area of the two mutually facing surfaces of the two implant parts, the following changes occurred during the force action:
On the force-acting side, the dimension of the nominal dimension intended for the seal (defined gap) increases by a value ≥ 1 μm.

On the opposite Side of the force reduces the dimension of the intended for the seal nominal size (defined gap) at the same time by a value of ≥ 50 microns.

The experiment was carried out with the materials of a titanium alloy (Ti6Al4V) and a ceramic (ZrO ₂ ).

These Supported measurements the realization underlying the invention that a rigid or plastically deformable seal no protection against penetration representing bacteria in this area.

seals which are based on the principle of permanent deformation of a sealing body, only work with connections on whose components no forces act.

Dental implants serve to replace lost chewing organs and thus need Forces, so-called masticatory forces record and are permanently exposed to this. Even at low extra-axial forces and axial forces which exceed the mounting force of the screw, arise when using of a rigid or ductile sealing body columns, not again getting closed. Thus, you can these compounds are not referred to as bacteria-proof.

The for the surface pressure required forces can be generated in two ways. On the one hand, the sealing body during the Connecting the proximal and distal implant part between the Both implant parts are compressed when the type of connection - for example an axial screw - and the type and arrangement of the seal are chosen accordingly. Here an arrangement is advantageous in which the sealing body is the shape a circular disc having a central passage opening and between two radially extending surfaces of the distal and proximal implant part is arranged.

On the other hand, the seal can also have a sealing body, which expands after establishing the connection between the distal and proximal implant part. Such an arrangement can best be achieved if the surfaces of the two implant parts lie in the radial direction, so that a space to be filled by the seal between the proximal and the distal implant part emanates from a sealing body is filling, which has the shape of a short, possibly tapering to the distal end tube. It is advantageous if the sealing body has the elastic properties already described or is used in its contracted example by cooling state in the proximal or distal implant part, then the respective other implant part is connected to the first implant part and the sealing body then - for example, in sequence from warming - expands. The same principle is also applicable to a seal in which the sealing body has the shape of a circular disk with central passage order.

suitable Materials for the sealing body are biocompatible plastics, in particular elastomers or duromers. This is also a particularly suitable mixture of rubber and PTFE count. This mixture contains preferably carbon black as filler. Also, thermoplastic elastomers and elastomer alloys (e.g. Polypropylene from the group of polyolefins), thermoplastics (e.g. Perfluoroelastomers (PTFE, FFKM, FFPM) and polyetheretherketone (PEEK)) and thermosets (amino or phenolic plastic) or a silicone come as elastic plastic for the sealing body in question.

Advantageous It is when the elastic material of the sealing body elastically stretchable by at least 5% or is compressible. For example, in one embodiment the through the stop surfaces given distance between the facing surfaces of the both implant parts 250 μm, so that the seal has a nominal size of 250 μm. In this case, the sealing body should for example, 50 microns above the Nominal dimension (250 μm) of the seal be made so that after assembly already has a compression of 50 μm (20% Compression) arises. These sizes are set aspired ideal measure dar. The height The seal should be as small as possible in order to be aesthetic establish no height for the later tooth crown To give away; in particular come as nominal Dimensions between 0.1 mm and 3 mm in question. For The design is crucial that the seal also under action of chewing forces is only deformed in the range of their elastic deformability and also in subregions e.g. with lateral load always around compressed a minimum remains. The sealing body is thus when joining of the implant compressed only by the necessary degree, so that the Implant-abutment connection under all possible Circumstances one Ensures tightness. The measure of Compression is dependent the material and the thickness of the material when using a greater height of the seal could the possibility of compression of the Materials are lower around the movements in the sealing area to compensate.

For an expanding under heat sealing body, in particular plastics having a high thermal expansion coefficient of more than 75 × 10 ^-6 / K at 20 ° C are advantageous.

Preferably is at least one an outer surface of the Implant forming outer surface of the sealing body with coated on a metal or ceramic layer, the metallic or ceramic layer a penetration of bacteria in from the metal or ceramic layer covered sealing components prevented. Especially suitable is a nano-coating, for example with titanium particles. The sealing surface itself can consist directly of a biocompatible plastic or coated in the aforementioned manner. As material for the metal layer Titanium, silver or gold may also come in the form of a Component of an alloy in question. All surface materials The seals are mouth resistant and sterilizable and take no or very little water on.

Of the sealing body In addition to elastic plastic may also contain a metal spring, For example, in the form of a diaphragm spring, the permanent elasticity and resilience of the sealing body ensures. This can be advantageous in particular in the case of a sealing body be, in which the elastic plastic at least partially Polytetrafluoroethylene (PTFE, Teflon) exists.

The The invention is based on the finding that a two-part dental implant does not have a microgap in the area of the bone exit point since exactly at this point the implant-abutment connection (IAV) is located, ie the connection between the proximal and distal implant part. These Compound causes a micro-gap, this micro-gap in turn is the subject of current scientific discussion. It It is known that the bone is about 0.5 mm below the implant-abutment connection (provided they are exactly at bone level lag). Proved to be adjacent to the implant-abutment connection Tissue (gums and bones) has signs of inflammation. demonstrably Among others, there are polymorphonuclear leukocytes that are bacterial Priority is given to induced processes. As a reason for this phenomenon the leakage of IAV and its colonization by bacteria is discussed.

The Result of bone loss is a gum decline with the episode longer expectant teeth (Implant crowns). In esthetic demanding regions, such as in the anterior region, represents the Bone loss a big one Problem.

The sealing body is preferably in the form of a ring extending between two perpendicular to the longitudinal Axial of a respective implant part extending stop surfaces is to be arranged and ensures a bacteria-tight seal. Such a sealing body or sealing ring is preferably made of a plastic material which has a greater elasticity or a lower hardness than the material of the two implant parts. The two implant parts are preferably made of a biocompatible metal, ceramic or plastic.

In an advantageous embodiment of the two-piece dental implant extend the facing surfaces of the both implant parts, between which the seal is arranged, transverse to the longitudinal axis of the dental implant - ie in radial direction - and parallel to each other. Such surfaces are particularly suitable between them a sealing body to arrange, which has the shape of a circular disc with a central passage opening. The central passage opening allows the connection between the proximal and distal implant part by means of a running in the axial direction of the implant Produce bolt. The bolt also allows the sealing body sufficiently compress it to the desired one surface pressure between its sealing surfaces and the surfaces the implant parts comes. The surface pressure is here by the touching one another stop surfaces limited. In certain applications, it is advantageous if the sealing body thicker in the area of its outer edges is as in a middle area of the seal. In this way can the sealing body in the area of their edges when joining deformed by the proximal and distal implant part, that its sealing surfaces on the surfaces of the exactly fit both implant parts. In alternative embodiments can the sealing body However, also have mutually parallel sealing surfaces or be designed in the manner of an O-ring.

According to one preferred embodiment has a distal partial shaft forming a distal implant part a longitudinal opening open towards its proximal end with an inner wall on, which has a basic geometry with circular cross-section and in the v-shaped, recessed open recesses towards the proximal end of the sub-shaft are. An abutment shaft forming a proximal implant part has at its distal end an outer wall with a basic geometry with circular Cross - section, in the longitudinal opening of the distal part of the shaft fits.

Preferably has the outer wall of the structural part shaft in the region of the distal end of the V-shaped projections, the so to the v-shaped Recesses of the distal part of the shaft are adapted that flank sections of the V-shaped depressions of the distal part of the shaft with flank sections of the V-shaped projections of the Aufbauschaftschaftes cooperate such that the V-shaped projections of the Aufbausilschaftes like a wedge in the V-shaped depressions of the distal part of the shaft push in until each two flanks of a v-shaped projection and two flanks of a v-shaped Depression touch each other and in this way the relative position of the distal part of the shaft and Structural member shaft both in the axial and in the rotational direction free of play, when the distal part of the shaft and the abutment shaft are in contact with each other be connected, or connected to each other. The touching each other Flanks act as stop surfaces form a defined height stop. The height stop will by a defined geometric shape of the implant parts themselves shown. Thus, the top of the proximal implant part (Proximal Teilschaft) acting forces only on the distal Transfer implant part (distal part). Would the acting forces no over the described height stop but about A seal would derive this seal over the Duration of use destroyed become.

there the design of the distal part of the shaft offers the advantage that he also record a body section without V-shaped projections can, so that the interconnected subshafts result in Although not exactly fixed in the axial direction to each other but in a rotary direction. This is particularly advantageous if the shaft is used to attach a web. Then it's up to you the bridge no further element necessary. The practitioner must join the inclusion only a single coherent element with the im Screw the patient's implant fixator into place.

The Flanks of the V-shaped projections or depressions extend with respect to a perpendicular to longitudinal axis the implant extending cross-sectional plane preferably radially to the outside and thus run perpendicular to the circumferential direction. This will be over the Radial forces transmitted after mounting the implant touching flanks, for example, blow up a distal part of ceramic could.

If the distal part of the shaft consists of a more tensile material such as metal, in particular titanium, the flanks may also be inclined relative to the above-described strictly radial orientation such that to a respective projection of the abutment shaft (ie the proximal implant part) or to a respective Deepening of the distal part of the shaft (distal implant part) belonging flanks converge in the outward direction. For example, the flanks can be inclined by 45 ° relative to the radial direction and thus also with respect to the circumferential direction. Thus, the flanks have a centering effect not only in terms of the direction of rotation, but also in the lateral direction.

The Basic geometry of the outer wall the Aufbausilschaftes is advantageously at least in the area the v-shaped projections conical. Correspondingly, the basic geometry is also advantageous the inner wall of the longitudinal opening of the distal Teilschaftes at least in the area of the V-shaped depressions conical.

For certain use cases and in particular if the distal part is made of ceramic, It may be advantageous if the basic geometry of the outer wall of the body section as well as the basic geometry of the inner wall of the Longitudinal opening of the distal part of the shaft at least in the region of the V-shaped depressions are cylindrical.

In both cases is the fit between outer wall of the abutment shaft and inner wall of the distal part shaft at least in the area of the V-shaped depressions preferably a clearance fit.

Besides, they are preferably at the distal part of the shaft as well as on the body part four v-shaped Wells, or V-shaped projections provided, the evenly on the scope of the respective sub-division are distributed. To this Way arise in the direction of rotation between the distal part shaft and Aufbausilschaft four well-defined positioning options. Alternatively you can also more or less projections and depressions of a corresponding number may be provided, which preferably over the extent of the respective sub-division are equally distributed. Suitable numbers are e.g. 3, 6 or 8.

Also a projection with a wide open V-shape (obtuse V-angle) in conjunction with a corresponding recess in the distal part of the body make sense.

When V-angle (opening angle the respective V-shape) are angles between 10 ° and 170 ° into consideration. In the sense of a self-centering embodiment it is advantageous if the V angle is smaller than that Point angle of the respective friction cone, which is due to the Material pairing in the area of the opposite Flanks of the V-shaped projections or recesses results.

One own aspect of invention also affects others, as the here realizes realized way, is that of those faces a distal part of the shaft and a proximal abutment shaft, when joining the two subshafts can meet each other, before the two subshafts their final Have assumed axial position relative to each other, no end face in one perpendicular to the longitudinal axis the two subshafts extending level lies. In known two-part shanks for dental implants with a rotation lock, usually such perpendicular to the longitudinal axis have running faces, which can collide at relatively twisted subshafts before the two subshafts completely in the desired Are pushed into each other, there is a risk that a more proximal Construction branch at a distal branch in a twisted Position is attached, which has the consequence that from this wrong assembly resulting shaft has a greater length than intended, because the two subshafts not yet final are pushed into each other. Which actually limits the relative axial position of the two partial shafts provide NEN final adjustments have not touched each other in that case because due to the twisting of the two partial shafts relative to each other previously at least one other perpendicular to the longitudinal axis of a respective sub-shaft running surface on an opposite surface of the each other has come across, which is not actually for engagement with the perpendicular to the longitudinal axis of the first sub-shaft extending face is provided. There is also no automatic correction the angle of rotation error, because the two in this way to each other abutting surfaces not in the manner of an oblique Plane can slide on each other and thereby automatically cancel the rotation angle again.

at known shafts for dental implants need a attending physician or a technician make sure that the both partial shafts without rotation angle, so that the two partial shafts are not be fixed in a wrong position relative to each other.

at the shaft according to the invention This problem is avoided by having none of these perpendicular to the longitudinal axis of the respective sub-shaft extending faces - except for the final longitudinal end stop surfaces provided are. This is specifically indicated by the V-shaped depressions respectively V-shaped projections reached. But there are also other geometric solutions conceivable.

When telescoping the two partial shafts, the oblique surfaces of the opposite, V-shaped depressions or V-shaped projections meet each on an inclined plane. When further joining the part shanks slide the colliding flank surfaces to each other until the two partial shafts have taken their axial relative end position to each other and have taken the correct angle of rotation to each other.

suitable Materials for the distal and the proximal implant part are in particular Metals such as steel or titanium, but also ceramics or plastic.

In The figures is an embodiment a shaft according to the invention for a Dental implant closer shown. From the figures show:

1 a perspective view of a Aufbausilschaftes as a proximal implant part;

2 a perspective view of the distal part of the shaft as a distal implant part;

3 a representation of the shaft with interconnected distal part of the shaft and abutment shaft, the distal part of the shaft is shown partially transparent;

4 : the distal partial shaft and the abutment shaft in the manner of an exploded view in perspective view;

5 a longitudinal section through the shaft; and

6 : a cross section through the shaft of 5 with DD designated place.

7 a preferred design of the outer axis of the shaft outer surfaces of the distal part of the shaft and proximal Aufbauschaftschaft and a sealing ring in a sectional view;

8th : the outer contour of a preferred transition from proximal to distal part of the shaft in a perspective external view;

9 A longitudinal section of a variant of a bodywork shaft according to the embodiments in FIGS 7 and 8th perspective view;

10 a detail view of a two-part dental implant with gold seal;

11 an alternative embodiment of a seal;

12 an exemplary sealing body with nano-coating and integrated Metallferderelementen in cross section; and

13a to c: the principle of facing abutment surfaces, which limit the maximum compression of the seal.

In the case of the two-part dental implant depicted in the exemplary embodiments, a proximal implant part is formed by a abutment shaft 10 and a distal implant portion of a distal portion 20 educated.

In again 1 reproduced perspective view of the body section 10 can be seen, this has a longitudinal section 12 , with one extending to the distal end 14 of the construction company shaft 10 towards tapering, conical basic geometry. The cone angle is 10 °. In the area of this conical longitudinal section 12 points the bodywork shaft 10 a total of four V-shaped projections 16 on, with their tips to the distal end 14 of the construction company shaft 10 clues. The four V-shaped projections 16 act as triangular prongs and are symmetrical and equidistant from each other about the circumference of the conical longitudinal section 12 of the construction company shaft 10 arranged. This results in eight obliquely to the distal end 14 of the construction company shaft 10 pointing flank surfaces 18 ,

In 2 is the distal part 20 shown in perspective. This has one to its proximal end 22 towards open longitudinal opening with an inner wall 24 , which also has a cone-shaped basic geometry. In the inner wall 24 are four v-shaped depressions 26 let in, obliquely to the proximal end 22 of the distal part of the shaft 20 indicative flank surfaces 28 exhibit.

If the distal part 20 and the proximal abutment shaft 10 are interconnected (see 3 ), is the relative position of the two partial shafts both in the axial direction and in the rotational direction by closely spaced flank surfaces 18 respectively 28 precisely defined. The sloping flank surfaces 18 respectively 28 The V-shaped projections or depressions thus form facing abutment surfaces, which approximate the two surfaces facing each other 32 and 34 (please refer 6 and 7 ) and thus the maximum compression of the seal 30 ( 6 and 7 ) limit. This is in 12a to 12c pictured. In particular shows 12c how the surfaces are 18 and 28 in the assembled state of the dental implant touch and thus form a longitudinal stop.

An exact centering of the two partial shafts takes place during assembly by the respective opposite, sloping flank surfaces 18 respectively 28 the v-shaped projections or depressions. When inserting the body section 10 in the longitudinal opening of the distal part of the shaft 20 meet the oblique flank surfaces 18 respectively. 28 the projections or recesses each on an inclined plane. The construction section 10 thus slides on further insertion in the longitudinal opening of the distal part of the shaft 20 until it reaches its axial end position and rotates so far until all opposing flank surfaces 18 and 28 have even contact with each other. This will make the body section 10 without a slide obstacle forced into its desired end position and can then be fixed by a running in the longitudinal direction of the shaft screw. The screw is tightened with a force of 30 Ncm.

The simultaneously serving as a longitudinal stop and the anti-rotation, corresponding flank surfaces 18 and 28 are then advantageously in the interior of the longitudinal opening of the distal part of the shaft 20 submerged and are not like other systems in the area of the implant shoulder. The implant shoulder can thus be kept at exactly the same level.

At the in 1 to 5 illustrated embodiments, no special measures are shown to make the transition from the proximal abutment shaft to the distal part of the shaft in the region of the outer contour of the fully assembled stem bacteria-tight.

According to the in 6 illustrated embodiment is a sealing ring for this purpose 30 provided between an outer end face 32 of the proximal abutment shaft 10 ' and one of these opposite, outer end face 34 of the distal part of the shaft 20 ' is arranged. When the stem is fully assembled, ie when the proximal abutment stem 10 ' and the distal part 20 ' have taken their final relative axial position to each other, is the sealing ring 30 compressed in the axial direction. The sealing ring 30 consists of a biocompatible plastic.

In the 7 perspective view of the exterior 6 illustrated longitudinal sections of Aufbausilschaft 10 ' and distal part 20 ' shows that the outer contour of the finished mounted shaft in the transition region of Aufbausilschaft 10 ' to the distal part 20 ' has no gussets where there is a risk of permanent bacteria settling in them.

9 shows a longitudinal portion of the proximal Abbausilschaftes 10 ' in perspective view. It is a seat 36 to recognize for the sealing ring in the form of a radially open, circumferential recess as well as the already with respect to 1 to 6 discussed v-shaped protrusions 16 ,

In 10 is pictured as a seal similar to the one in 7 illustrated embodiment variant can be designed when the sealing body is not made of an elastic material, but of a ductile material such as gold. While the sealing body according to the variant of 7 has the shape of a circular disk with a large, central passage opening are the sealing surfaces of the sealing body 30 ' not even, but are at the outer edge of the sealing body in the axial direction of the implant before and form in this way beads 42 and 44 each with triangular cross-section. These beads are deformed when tightly connecting the proximal and distal implant part, thus producing a secure seal. This is in 10 indicated by dashed lines.

11 shows a seal with a sealing body 30 '' made of an expandable material such as expandable metal or a plastic with a high coefficient of thermal expansion. The sealing body 30 '' out 11 has the shape of a pipe section. Accordingly, the gap between the proximal and distal implant part 10 '' respectively 20 '' designed.

12 shows by way of example how the sealing ring 30 out 6 to 8th can be built inside. An elastic plastic body 46 preferably made of PTFE contains two mutually opposing disc springs 48 made of stainless steel. In alternative embodiments, the springs may also be made of another resilient material, such as titanium or a plastic such as PEEK. Also, the springs may have a different shape, as long as they exert a spring action in the direction indicated by the dotted line longitudinal direction of the sealing body.

Outside is the plastic body 48 with a few nanometers thick layer 50 covered, which contains titanium particles in the illustrated preferred embodiment. The thickness of the layer 50 is greatly exaggerated in the figure to make the layer visible. Such a nanocoating can be provided on all outer surfaces of the sealing body, regardless of the outer shape of the sealing body.

Claims (29)

Two-part dental implant having a distal and a proximal implant part, which in an interconnected state at an intermediate point at least indirectly adjacent to each other and in the region of the junction with each other facing surfaces, wherein - between the mutually facing surfaces of the distal and proximal implant part, a sealing body is provided which has the surfaces facing sealing surfaces which tightly abut in the final connected state of the two implant parts on their facing surfaces, and also - between the distal and the proximal implant part facing each other abutment surfaces are provided which abut one another in the assembled dental implant and which limit the degree of approach of the two facing surfaces of the implant parts, between which the sealing body is arranged, so that the abutment surfaces a minimum distance of the two each other Defined facing surfaces of the implant parts, which is bridged by the sealing body, characterized in that the sealing body consists at least partially of an elastic material. Dental implant according to claim 1, characterized in that that the facing surfaces transverse to a longitudinal axis of the dental implant and parallel to each other. Dental implant according to claim 1, characterized in that that the facing surfaces are conically shaped, have the same cone angle and concentric to each other and to a longitudinal axis of the dental implant are arranged. Dental implant according to one of claims 1 to 3, characterized in that the sealing body takes the form of a circular disk with central passage opening Has. Dental implant according to one of claims 1 to 4, characterized in that the sealing body has concave sealing surfaces, so that the material thickness of the sealing body at least in the relaxed Condition in the region of its peripheral edge is greater than in a middle Area of the sealing body. Dental implant according to one of claims 1 to 5, characterized in that the elastic material of the sealing body to at least 20% of an expansion direction elastically compressible is. Dental implant according to one of claims 1 to 6, characterized in that the elastic material of the sealing body a Plastic is. Dental implant according to claim 7, characterized in that that the plastic is an elastomer, thermoplastic or a duromer blend is. Dental implant according to one of claims 1 to 8, characterized in that the seal in addition to plastic metal or ceramic components, which are preferably an integral part of the sealing body are. Dental implant according to claim 9, characterized in that at least one of an outer surface of the Implant forming outer surface of the sealing body coated with a metal or ceramic layer, wherein the Metal or ceramic layer a penetration of bacteria into the metal or ceramic layer covered sealing components prevented. Dental implant according to claim 10, characterized that the metal layer contains titanium, silver and / or gold. Dental implant according to one of claims 1 to 9, characterized in that at least the sealing surfaces of sealing body Made of an elastic, biocompatible, mouth-resistant, sterilizable plastic consist. Dental implant according to claim 7 to 12, characterized in that the plastic has a thermal expansion coefficient of more than 75 · 10 ^-6 / K at 20 ° C. Dental implant according to claim 1 or 3, characterized that the sealing body in a radial clearance between the surfaces of the distal and and proximal implant part is arranged, wherein the expansion of the sealing body is larger in the radial direction, as the clearance between the distal and proximal implant part in their complete interconnected state. Dental implant according to claim 2, having a shaft which is divided into two parts in the longitudinal direction and has a distal part shaft as a distal implant part for implantation in a jawbone and a proximal abutment shaft as a proximal implant part on which an artificial dental crown is to be constructed, and wherein a proximal end of the distal one Partial shaft and the distal end of the Aufbauteilsschaftes are geometrically matched to each other and adjacent to each other in the implanted state of the shaft, characterized in that the distal part of the shaft has a proximal end of the distal part of shaft open longitudinal opening with an inner wall having a basic geometry with a circular cross-section , wherein in the inner wall V-shaped, to the proximal end of the distal part of the shaft open recesses are recessed, and that the body portion has at its distal end an outer wall having a basic geometry with a circular cross-section which fits into the longitudinal opening of the distal part of the shaft. Dental implant according to claim 15, characterized in that that the outer wall of the abutment shaft has V-shaped projections in the region of its distal end, the so to the V-shaped Wells of the distal branch are adapted to that interconnected distal subshaft and abutment shaft Flank sections of the V-shaped depressions and the V-shaped projections touching each other interact and limit the compression of the seal, facing stop surfaces form. Dental implant according to claim 15 or 16, characterized characterized in that the distal part of the shaft four of the V-shaped depressions that evenly over the Scope of the inner wall are distributed and that the construction part shaft corresponding to four of the V-shaped ones projections which also equally over the Scope of the outer wall distributed are. Dental implant according to claim 16, characterized that the basic geometry of the outer wall the Aufbausilschaftes in the region of the V-shaped projections conical is. Dental implant according to claim 18, characterized in that that the basic geometry of the inner wall of the longitudinal opening of the distal part of the shaft in the area of the V-shaped Recesses is conical. Dental implant according to one of claims 15 to 19, characterized in that between two when fully assembled Shank opposite each other and with respect to the radial direction of the shaft outer faces the sealing body is arranged and acts as a seal, the sealing body so is dimensioned that it compresses in the axial direction of the shaft is when the distal branch and the proximal abutment shaft their final, have taken axial relative position to each other. Dental implant according to claim 20, characterized that the sealing body the shape of a circular Has sealing ring with rectangular material cross-section. Dental implant according to claim 20 or 21, characterized characterized in that the sealing body of a biocompatible Plastic is made. Dental implant according to one of claims 15 to 22, characterized in that the distal part of the shaft and / or the proximal abutment shaft made of biocompatible metal are. Dental implant according to claim 23, characterized the metal is titanium or a titanium-containing alloy. Dental implant according to one of claims 15 to 22, characterized in that the distal part of the shaft and / or the proximal part are made of ceramic. Dental implant according to claim 25, characterized that the ceramic is hipped and polished or polished. Dental implant according to claim 25 or 26, characterized in that the ceramic ZrO ₂ , ZrO ₂ / Al ₂ O ₃ / Y ₂ O ₃ (ATZ), ZrO ₂ / Y ₂ O ₃ (TZP) or ZrO ₂ / Y ₂ O ₃ / Al ₂ O ₃ (TZP-A). Dental implant according to one of claims 15 to 22, characterized in that the distal part of the shaft and / or the proximal part is made of plastic. Dental implant according to claim 28, characterized in that that the plastic contains polyetheretherketone (PEEK).