DE3515154A1 - Intraossal implant - Google Patents

Abstract

The invention relates to an intraossal implant for fastening of firmly seated or detachable dental replacements, comprising two mutually connectable parts, one of which is designed as a primary cylinder which can be inserted in the jaw bone and is anchored therein positively and/or non-positively and having a central longitudinal bore, and the other part of which is designed as a secondary cylinder having a peg which can be inserted in the longitudinal bore in the primary cylinder and is detachably held therein, and which is designed on its free upper end for connection of the dental replacement, as a result of which it is possible to create an implant comprising a primary cylinder and a secondary cylinder held therein which provides positive and non-positive connection to the bone and ensures load-free stabilisation of the primary cylinder, and in which the implant is not subject to any plastic deformation and its mechanics are maintenance-free.

Description

The invention relates to an intra-osseous implant for loading

consolidation of fixed or removable dentures, consisting of of two interconnectable parts, one of which is called the jawbone Primary cylinder that can be introduced and anchored in this form-fitting and / or force-fitting manner with a central longitudinal bore and the other part is designed as a secondary is that one introduces into the longitudinal bore of the primary cylinder-n? and in this has releasably held pin which at its free upper end for the connection of the dental prosthesis is formed.

According to DE-OS 31 49 881 is a connecting element for endosseous Implants known, with the help of which one by overloading the implant bed and the resulting regression of the bone caused loosening of the implant should be avoided. Measures for redirecting the dentures are vertical here Forces acting on the main axis of the implant are provided into the interior of the implant, the more even distribution of that exerted by the implant on the implant bed To achieve tensions. For this purpose, the dentures are firmly aligned with the axis metallic materials connected that form the interior of a cup-shaped implant body penetrated coaxially and in a space between the axis and the implant body filling bed made of elastic material is pivotably mounted, the pivot axis is formed from a stationary arranged on the axis of rotation ball, whose Diameter of the clear width of the implant body.

However, the disadvantage of this implant is that the fulcrum of the implant post is approximately in the middle of the implant body, so that loosening of the implant cannot be avoided with certainty. It is also a flawless one Discharge of occurring tension forces in the outer area of the implant body is not guaranteed, so that there is damage and high horizontal pressure loads of the dental prosthesis can lead to fracture of the implant body, especially if when the implant body consists of a ceramic material.

According to the patent .... (patent application P 34 40 952.1) is an enossal Implant for fastening fixed or removable dentures, consisting of of two interconnectable parts, one of which is called the jawbone The primary cylinder that can be brought in and that is firmly anchored with it a longitudinal bore and the other part is designed as a secondary cylinder, the one that can be introduced into the longitudinal bore of the primary cylinder and detached from it held pin and a coaxially arranged in the secondary cylinder, on his free upper end has the dental prosthesis-bearing implant post, which by means of a joint connection, e.g. through a form fit, force fit or material fit, completely or only closed a part in the secondary cylinder and in the implant attachment, which is preferably consists of aluminum oxide ceramic, is held, formed in such a way that the Implant posts made from a brittle material of a those occurring in the area of the dental prosthesis due to the masticatory muscle force acting on it Vibrations with simultaneous displacement of the fulcrum of the implant post diverting into the lower area of the secondary cylinder from there into the primary cylinder, tubular or ring-shaped power system is surrounded, the several contiguous Areas with different elastic properties such that on a bottom, inelastic area, areas with low elasticity and in turn, these areas adjoin areas with strong elasticity. The power transmission system surrounding the implant post consists of a lower one Module system or several lower module systems made of inelastic material, one adjoining middle module system made of a slightly elastic material and an adjoining upper module system made of a highly elastic one Material, with the upper module system extending into the implant attachment.

The invention is based on the object of a primary cylinder and an intra-osseous implant held in it to create, with which a form-fitting and force-fitting connection to the bone is achieved and with which a load-free stabilization of the primary cylinder is ensured and the implant is not subject to any plastic deformation and is maintenance-free Has mechanics. Further supposed to be the implant of the patent ... (P 34 40 952.1) can be improved.

In the case of an endosseous implant, this task is carried out in accordance with the introduction described type solved in such a way that the pin of the secondary cylinder as Vibrating rod is designed that on the pin an upper module tube from a strong arranged elastic material connected to the pin by an adhesive connection is that the primary cylinder in the interior of its longitudinal bore at a distance of the longitudinal bore inlet opening with the formation of a modular tube-free, when inserted Secondary cylinder has an air gap forming section a guide tube, which is held in the primary cylinder by means of an adhesive connection, with on the module tube an implant attachment with one with the longitudinal bore of the primary cylinder aligned central perforation is arranged on the surface of the primary cylinder is held slidably, while the vibrating rod of the secondary cylinder in the guide tube by one on the vibrating rod when the secondary cylinder is inserted in the area of the Guide tube arranged thermal lock is held.

With an implant designed in this way, a shape and / or frictional connection of bone and implant achieved, this connection by the outer coating of the primary cylinder with a hydroxyapatite ceramic is improved. In addition, the primary cylinder stabilizes stress-free and the S&D cylinder, ready for assembly, consists of just one single part. One Composition of several individual parts of the secondary cylinder in the mouth of the patient is omitted, so that a quick and easy handling by is given to the implanter. Furthermore, there is an optimal freedom from gaps through the Construction that maintains a constant tension of the secondary cylinder against the primary cylinder guaranteed by the iemo lock used, the sliding zones and the Introduction of the secondary cylinder into the primary cylinder under a defined pressure. There is also an imitation of the periodontium by sliding. One absolutely The mechanics are maintenance-free and wear-free, as the implant is only elastic has deformable parts that are not subject to any plastic deformation, so that no more plastically deformable parts have to be replaced. It is not applicable a large part of the aftercare through maintenance-free mechanics of the implant. Through this there is a guarantee of freedom from gaps and considerable time savings for the implanter. The energy flows in the implant are controllable because they are plastic Deformable parts are avoided, thus reducing the use of the bioactive coated body-friendly material aluminum oxide ceramic is promoted, whereby a Risk of breakage is excluded. The fact that the vibrating rod through the thermal lock in the guide sleeve of the primary cylinder after inserting the secondary cylinder is anchored, offset dynamic, vertical, horizontal and attached to the vibrating rod Torsional forces cause the vibrating rod to vibrate degraded in heat that is released into the interior of the implant. Quantitatively not converted into heat low mechanical energies are over in the locking point or in the storage area the primary cylinder delivered to the bone. The locking point is optimal in the Placed in the middle of the vertical axis of the primary cylinder. The vibration amplitudes are designed in such a way that the primary cylinder is not mechanically stressed will.

The periodontium is imitated by controlled sliding displacement of the implant attachment on the primary cylinder, dampened by the permanently elastic upper module tube. By bringing the secondary cylinder into the primary cylinder under a defined pressure, there is no gap in the area of the sliding zones.

Advantageous refinements of the invention are set out in the subclaims marked.

Embodiments of the invention are described below with reference to Drawing explained in more detail. It shows in enlarged representations F i g. 1 a endosseous implant consisting of a primary cylinder and a secondary cylinder, partly in view, partly in a vertical section, FIG. 2 the primary cylinder in a vertical section, F i g. 3 the secondary cylinder in a vertical Section, F i g. 4 a further embodiment of an intraosseous implant, partly in view, partly in a vertical section, F i g. 5 the primary cylinder of the implant according to FIG. 4 in a vertical section and FIG. 6 the secondary cylinder of the implant according to FIG. 4 in a vertical section, FIG. 7 another Embodiment of an endosseous implant, partly in view, partly in a vertical position Section, F i g. 8 an enlarged detail of the transition b.

rich module tube-implant attachment -secondary cylinder in the embodiment according to FIG. 7.

The intraosseous implant shown in FIGS. 1 to 3 consists of a primary cylinder 10 and a secondary cylinder 100, the so-called working cylinder.

The primary cylinder 10 consists of a rigid body, in particular made of aluminum oxide ceramic and is coated on the outside with a hydroxylapatite ceramic.

This outer coating is denoted by 15. As can be seen from Fig. 2, the outer coating 15 does not extend over the entire area of the primary cylinder 10, which will be discussed in more detail below. This primary cylinder 10 is the actual implant body and has a central longitudinal bore 11 which forms the interior.

The secondary cylinder 100 becomes the primary cylinder after implantation 10, i.e. about 3 months after implantation, into the longitudinal bore 11 of the primary cylinder 10 is used, creating the connection between the implant and the dentures will be produced.

The secondary cylinder 100 has an oscillating rod Pin 111 on which an upper module tube 20 is arranged, which consists of a highly elastic material, which can be metallic, but also made of plastics or other suitable materials. This module tube 20 is in the upper Area of the pin 111 of the secondary cylinder 100 arranged and by means of a Adhesive bond held.

In the interior of the longitudinal through hole 11 of the primary cylinder 10, and although at a distance from the opening 11a of the longitudinal through hole 11 is a guide tube 30 arranged. The section of the modular tube 20 and the guide tube 30 is free of modular tubes and when the secondary cylinder 100 is inserted into the primary cylinder 10, it forms a Air gap, which is indicated at 25 (Fig. 1).

The guide tube 30, which extends over a larger area of the Length of the primary cylinder 10 extends, is in the primary cylinder 10 by means of a Glued connection firmly arranged.

The secondary cylinder 100 consists of a cylinder inserted into the longitudinal bore 11 of the primary cylinder 10 insertable pin 111, which is suitable as a vibrating rod Materials consists, and an upper head-like extension 115, the mounting head forms and receives a mounting cap 130 which is detachably held on the mounting head 115 is.

The implant attachment 40 is placed on the module tube 20, the with a central through-hole corresponding to the outer diameter of the module tube 20 41 provided is. In the embodiment shown in FIGS the implant attachment 40 has a cylindrical shape and an outer diameter, which corresponds approximately to the outer diameter of the primary cylinder 10, but The outer diameter of the implant attachment 40 can also be compared to the outer diameter of the primary cylinder 10 have a smaller diameter, so that then the outer diameter of the implant attachment 40 corresponds to the outer diameter of the mounting cap 130. This mounting cap 130 consists of metallic materials, in particular noble metallic materials Materials.

While in the embodiment shown in Figs. 1 and 2 of the Implant the sliding surface 12 in the upper region of the primary cylinder 10 perpendicular to the longitudinal axis of the primary cylinder 10 and thus running horizontally is the sliding surface 12 of the primary cylinder 10 for the implant attachment 40 according to the embodiment 4 and 5 designed as a dome with an angle t of in particular 9.270. In this embodiment, the upper implant attachment, designated 40 (Fig. 6) designed as an approximately cylindrical shaped body, the outer wall surface 40b of which is in the shape of a circular arc is drawn in and its lower outer diameter is approximately the outer diameter of the Primary cylinder 10 corresponds, while the upper outer diameter of the implant attachment 40a is dimensioned larger than the lower outer diameter. Furthermore is the lower bearing surface 40 c of the implant attachment 40 of the sliding surface 12 of the primary cylinder 10 designed so that the implant can slide properly essay 40a on the primary cylinder 10 is guaranteed. This is the implant attachment 40a is slidably held on the surface of the primary cylinder 10.

The vibrating rod 111 of the secondary cylinder 100 is in the guide tube 30 anchored. The outer diameter of the vibrating rod 111 corresponds approximately to that Inner diameter of the longitudinal bore 11 of the primary cylinder 10, so that the vibrating rod 111 is held with a tight fit in the longitudinal bore 11 of the primary cylinder 10.

Furthermore, the vibrating rod 111 of the secondary cylinder 100 is by means of a thermal closure 50 held in the primary cylinder 10 (Figs. 1 and 3). This Thermal closure 50 is approximately in the middle of the primary cylinder 10 or the guide tube 30 and consists of a wire 51 made of bimetal (e.g. memory metal), the is held in an annular groove 112 which is formed in the vibrating rod 100. In the same way as the vibrating rod 111 by means of the thermal seal 50 in the Primary cylinder 10 is held, the mounting cap 130 is also on the mounting head 115 held. Here the thermal seal is designated 150 and also exists from a wire 151 made of bimetal (e.g. Morymetall), this wire 151 in a Annular groove 116 is held in the mounting head 115 (Fig. 3).

The mounting head 115 is, as shown in FIG. 3, conical upwards rejuvenated.

The outer coating 15 on the primary cylinder 10 consists in particular made of a hydroxyapatite ceramic.

As FIG. 5 shows, this outer coating 15 only extends over a portion of the primary cylinder 10, and over the bigger one Area of the primary cylinder.

The upper area of the primary cylinder has no external coating. This section without any external coating represents the contact zone A, that of the cortex corresponds, while the contact zone B corresponding to the cancellous bone corresponds to this outer coating 15 carries.

To reduce the torque, dynamically apply the mounting cap 130 and thus transferred to the head 115 of the vibrating rod 111 of the secondary cylinder 100 Horizontal forces cause the vibrating rod 111 to vibrate. A torque is created.

This torque is reduced via the vibrating rod, and how follows: The implant attachment 40 slides on the surface 12 of the primary cylinder 10. Part of the torque is consumed by the sliding friction that occurs here. In the case of the implant according to FIG. 4, this sliding surface 12 is designed as a spherical cap, and advantageously with an angle of 9.270. Since the implant attachment 40 slides on the primary cylinder 10 into this area, no canting can occur and no breakouts occur, as is the case with flat surfaces and the high surface pressures can be done if this is provided. The surfaces do not slide dry but wet on each other.

This moisture is guaranteed by the aluminum oxide ceramic material used. This has the property that free oxygen ions are available on its surface that automatically become one with substances from the surrounding environment connect fine film of lubricant.

The material itself ensures that it is self-lubricating on the sliding surface. This property of the aluminum oxide ceramic leads to a high Self-lubricating effect.

The upper module tube 20 is made of a highly elastic material and acts like a vibration damper.

This damping turns another part of the torque into heat reduced. The air gap 25 is located under the upper module tube 20, so that in its oscillation range S of the oscillating rod 111 of the one used in the primary cylinder 10 Secondary cylinder 100 can swing freely. The vibrations that occur are degraded in heat.

In the embodiment shown in Figure 6, the implant has Set 40a has a different shape compared to the implant attachment 40. The implant attachment 40a is designed as an approximately cylindrical shaped body, the outer wall surface 40b is drawn in a circular arc and its lower outer diameter is approximately the outer diameter of the primary cylinder 10 corresponds, while the upper outer diameter is the same or larger outside diameter than the primary cylinder 10.

The guide tube 30 is located below the air gap 25 in FIG the interior of the primary cylinder 10. This guide tube 30 is in the primary cylinder glued in. The vibrating rod 111 of the secondary cylinder 100 fits precisely in the guide tube 30 anchored. In the upper area of the guide tube 30 is located on the vibrating rod 111 the thermal lock 50.

By anchoring by means of the thermal closure and by the Fits in the guide tube 30 are not dismantled in the manner described above Torques in the entire storage area L of the vibrating rod 111 over the guide tube 30 transferred to the primary cylinder 10, and not at specific points in the area of the thermal seal 50, but distributed over the entire area of the Guide tube 30. The remaining, distributed in this way delivered to the bone The torques are so slight that they exceed the hydroxyapatite coating 15 of the outer cylinder of the primary cylinder 10 produced solid composite of the primary cylinder no longer interfere with the bone. This "energy depleting" and "Bearing-friendly" mechanics therefore make it possible to use primary cylinders made of aluminum oxide ceramics with a wall thickness of only 0.9 mm and thus for the first time a more body-friendly one To produce late-stage implants made from aluminum oxide ceramics with a diameter of only 4 mm, because due to the torque-reducing mechanics of the primary cylinder 10 hardly any more is mechanically stressed.

Between the head 115 of the vibrating rod 111 of the secondary cylinder 100 - underside of the cone - and the implant attachment 40 there is an air layer 120 (Fig. 1). The vibrating rod 111 can thus as a result of horizontally acting forces swing. It is dampened by the upper module tube 20, which when the secondary cylinder is inserted 100 extends with a section into the interior of the longitudinal bore 11 of the primary cylinder 10 extends. Due to this configuration, the module tube 20 is at the same time Lead into the primary cylinder 10. The implant attachment 40 slides on the sliding surface, those from the bottom of the implant attachment 40 and the top the primary cylinder 10 is formed. Both surfaces are sanded flat and have a high gloss polished. With horizontal chewing forces on the head 115 of the vibrating rod 111 or the overlying mounting cap 130 therefore moves the secondary cylinder on the primary cylinder. The horizontal shift is designed for 150 mu, which corresponds to the mobility of the natural periodontium.

The mechanics that create the imitation of the natural periodontium, is absolutely maintenance-free.

It is also essential that the implant due to its constructive Design ensures a high level of gap tightness. The implant itself is made from only two parts, namely the primary cylinder 10 and the secondary cylinder 100. The thermal closure 50 used here consists of the wire 51 made of memory metal, which runs in the annular groove 112 which is let into the vibrating rod 111. By Expansion at body temperature anchors the thermal lock 50 to the vibrating rod 111 and thus the secondary cylinder 100 in the primary cylinder 10. The guide tube 30 is provided with a groove for the locking of the thermal lock. This groove forms an inclined plane in its upper part and a curve in its lower part, so that upon expansion of the rotating wire 51 made of memory metal, the secondary cylinder 100 is drawn into the primary cylinder 10. It arises from this in the area the sliding surfaces between the implant set 40 and the primary cylinder 10 a gap density that is both bacteria and moisture tight.

The guide tube 30 is under a defined pressure in the primary cylinder i0 glued, in which the air gap 120 between the head 115 of the vibrating rod 111 and the mounting cap 130 and the implant attachment 40 by an inelastic disk is bridged and the guide tube 30 is placed so that the thermal closure 50 developed a maximum of the defined tensile force. The dentist then needs the secondary cylinder 100 only to be introduced under the same pressure to ensure that the thermal lock snaps into the groove at the intended point and thus the specified one Train and the gap security is ensured. The contribution itself is carried out by The patient's bite on the mounting cap 130 using pressure gauges, which can be connected to a digital print reader.

The above-mentioned gap tightness is achieved in particular by the use of the two thermal closures 50, 150 corresponding to that shown in FIG Embodiment achieved.

Another embodiment of the implant is shown in FIGS 8, the basic structure of which corresponds to the embodiment according to FIG. That Module tube 20 is here in its upper end region 20a with a cantilever Disc-shaped or ring-shaped section 20b is provided, which attaches the implant attachment 40 (40a) partially overlaps, the section 20b extending radially over the Outside diameter of the mounting head 115 out into the area of an engagement groove 130a extends in the mounting cap 130 and at the same time the formation of an air gap 120 ensures. In this way it becomes possible to secure the module tube 20 both to be glued to the implant attachment 40 (40a) as well as to the assembly head 115 and thus to be connected securely and, at the same time, the formation of the air gap 120 ensure (Fig. 8).

It is in Fig. 7 a also in the other embodiments of the Implantable embodiment of the thermal closure 250 is provided. Here the vibrating rod 111 is parallel to the longitudinal axis of the vibrating rod 111, in the interior of a longitudinal through-hole 11a of the vibrating rod 111 extending into it Longitudinal openings 113a, 113b, 113c, 113d are provided. Wires are made from one Bimetal, such as a memory metal, through the longitudinal through-hole llla into the interior of the vibrating rod 111 inserted in such a way that it passes through the longitudinal openings 113a, 113b, 113c, 113d reach through to the outside and into the primary cylinder 10 inserted secondary cylinder 100 with the guide tube 30 of the primary cylinder 10 are in contact.

In this way it is ensured that the vibrating rod 111 is in the storage area L is held securely in the guide tube, so that here a large-area energy transfer the energy not already converted into heat in the oscillation range S on the Primary cylinder 10 is made possible.

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Claims (10)

T i t e 1: Endosseous implant Claims 1. Endosseous implant for the attachment of fixed or removable dentures, consisting of two interconnectable parts, one of which is considered to be in the jawbone The primary cylinder that can be brought in and that is firmly anchored in this a central longitudinal bore and the other part is designed as a secondary cylinder is, the one in the longitudinal bore of the primary cylinder can be introduced and in this has releasably held pin which at its free upper end for the connection of the dental prosthesis is formed, characterized in that the Pin (111) of the secondary cylinder (100) is designed as a vibrating rod that on the pin (111) an upper module tube (20) made of a highly elastic material is arranged connected by an adhesive connection to the pin that the primary cylinder (10) in the interior of its longitudinal bore (11) at a distance from the longitudinal bore inlet opening (lla) with the formation of a modulrohrf, in, with inserted secondary cylinder (100) an air gap (25) forming section has a guide tube (30) which in the primary cylinder (10) is held by means of an adhesive connection, wherein on the Module tube (20) an implant attachment (40, 40a) with one with the longitudinal bore (11) of the primary cylinder (10) aligned central through hole (41) is arranged, the on the surface of the primary cylinder (10) is slidably held while the vibrating rod (111) of the secondary cylinder (100) in the guide tube (30) through one on the vibrating rod (111) with inserted secondary cylinder (100) in the area of the guide tube (30) arranged thermal closure (50) is held. 2. Endosseous implant according to claim 1, characterized in that the vibrating rod (111) has a head-like extension (115) at its upper end and that between the head (115) of the vibrating rod (111) and the implant attachment (40) an air layer (120) is formed. 3. Endosseous implant according to claim 1 or 2, characterized in that that the upper module tube (20) in the interior of the through hole (41) of the on the primary cylinder (10) slidingly held implant attachment (40,40a) and arranged by means of a Adhesive connection is held on the module tube (20). 4. Endosseous implant according to one of claims 1 to 3, characterized characterized in that the upper module tube (20) at its upper end region (20a) has a cantilevered, disc-shaped portion (20b) and that the module tube (20) in the area of the section (20b) by means of an adhesive connection on the implant attachment (40,40a) and / or held on the head-like extension (115) of the vibrating rod (111) is. 5. Endosseous implant according to one of claims 1 to 4, characterized characterized in that the thermal seal (50) consists of a wire (51) made of bimetal, e.g. memory metal, which is arranged in an annular groove on the vibrating rod (111) (112) is held, 6. Endosseous implant according to one of claims 1 to 4, characterized marked, that the thermal seal (250) consists of one or more Wires (251) made of bimetal, e.g. memory metal, are inserted into the interior Longitudinal perforations extending into a longitudinal through hole (llla) of the vibrating rod (111) (113a, 113b, 113c, 113d) are arranged. 7. Endosseous Imp'-nXat according to one of claims 1 to 6, characterized characterized in that the sliding surface (12) of the primary cylinder (10) for the implant attachment (40,40a) is designed as a dome with an angle of in particular 9.270. 8. Endosseous implant according to one of claims 1 to 7, characterized characterized in that the implant attachment (40a) as an approximately cylindrical shaped body is formed, the outer wall surface (40b) is drawn in a circular arc and whose lower outer diameter is approximately the outer diameter of the primary cylinder (10) corresponds, with the upper outer diameter of the implant attachment (40a) opposite the lower outer diameter is equal to or larger, and that the lower Support surface (40c) corresponding to the shape of the sliding surface (12) of the primary cylinder (10) trained and this is adaptable. 9. Endosseous implant according to one of claims 1 to 8, characterized characterized in that the primary cylinder (10) has an outer coating (15) in particular made of hydroxyapatite ceramic. 10. Endosseous implant according to claim 9, characterized in that that the contact zone (A) of the primary cylinder (10) corresponding to the cortex is free of external coating while the contact zone (B) of the primary cylinder corresponding to the cancellous bone (10) carries the outer coating (15).