CH715121A2 - Endosseous dental implant. - Google Patents

Abstract

In order to improve the anchoring of an endosseous dental implant in the cancellous tissue of the jawbone, an endosseous dental implant comprising a screw sleeve (1) open on both sides, an expansion body (20) and an expansion bolt (10) is proposed. The screw sleeve is cylindrical or conical on the outside and cylindrical on the inside and has an external and an internal thread. At the coronal end, it has a bearing surface (5) for an abutment. The internal thread extends apically to a support bracket. The expansion body has a coronal ring and apical molded expansion arms (23), each with a lateral notch edge (26). The expansion bolt can be inserted into the expansion body and has a coronal head and an apical conical bolt part.

Description

description

TECHNICAL FIELD The present invention relates to an endosteal dental implant, comprising a screw-in part with an upper end (6) which is distal in the inserted state and a lower end (7) which is proximal in the installed state, the distal end (6) having a Bearing surface (5) is designed, which serves to support an abutment which can be fastened thereon, the screw-in part being cylindrical or conical on the outside and cylindrical on the inside and having an external thread (21) and an internal thread (22).

PRIOR ART Dental implants usually consist of an anchoring part for anchoring in the bone and a structural part for receiving an abutment to be applied or a crown, bridge or prosthesis construction. The anchoring part is usually designed as a hollow screw. Dental implants have been used successfully for more than thirty years. The majority of the dental implants currently used are metal dental implants made of titanium or titanium alloys. Implants made of the corresponding metals or made of titanium or titanium alloys bring about a safe composite osteogenesis, which is achieved after a healing period of three to four months. The primary stability of such implants is based primarily on screwing the anchoring part into the bone. The stability is ensured above all by the retention of the anchoring part and, in particular, its external thread in the cortical tissue of the jawbone. The forces in the causal direction are very high, but experience has shown that they are optimally absorbed by the cortical tissue. The density of the cancellous tissue beneath the cortical tissue varies greatly depending on the patient. If the density of the cancellous tissue is too atrophic, which the dentist can clearly see from the X-ray image, he will do a so-called bone build-up before placing an innate dental implant. For this purpose, bone material is injected into the jawbone or subperiostal bovine material, which is offered for example by Geistlich Pharmaceutical AG, or TGP / HA (tricalcium phosphate / hydroxyapatite) is used as the matrix material. After about three to six months you can see an improved ossification of the cancellous bone in the areas in which a so-called bone build-up has taken place. The cancellous bone can now have a stabilizing effect, but a rotation-securing effect, which creates a natural, dense cancellous tissue, cannot be guaranteed. Possibilities for obtaining improved rotational stability by means of an improved anchoring of the hollow screw in the jaw are only known to a limited extent. For example, WO 03/045 268 discloses a dental implant with an anchoring part in which the mounting part is formed in one piece on a zirconium oxide basis. To improve the composite osteogenesis, this ceramic implant has a special surface that is supposed to support ossification.

A large amount of dental implants are known from the patent literature, in which an improved anchoring is to be achieved via the special design of the thread. Such a solution is shown, for example, in WO 2008/128757. In the solution disclosed here, a helical groove is also milled into the implant screw to improve the osteogenesis, which is only provided with a blind hole in the distal region with an internal thread in order to produce a screw connection with an abutment. This solution, too, cannot avoid loosening the dental implant by slightly twisting the implant in the jawbone.

DESCRIPTION OF THE INVENTION It is therefore the object of the present invention to offer a solution which is intended to avoid unwanted loosening of the screwed-in dental implant in the jawbone.

It is a further object of the present invention to offer a solution which, in certain cases, makes a prior bone building unnecessary.

This object is achieved by an endosseous dental implant of the type mentioned in that the screw-in part is a screw sleeve open at both ends, the internal thread of which leads from the distal end to a bearing shoulder, and that the endosseous dental implant also comprises an expansion body which is distal in the installed state Ring with a terminal bead and a plurality of spreader arms formed proximally on the ring, each with a lateral notch edge, and distant a spreader bolt which can be inserted into the spreader body and has a distal screw part and a proximal conical bolt.

In the case of endosseous dental implants, the choice of material is important. Titanium alloys have been used in this area for decades. In the dental implant according to the invention, the screw sleeve and the screw bolt can be easily and preferably made from titanium alloy.

Dental alloys are hardly elastic and are therefore not suitable as a base material for the expansion body. Two materials are particularly suitable for this. A preferred embodiment provides for the expansion body to be made from a biocompatible plastic. These are, in particular, bio-inert plastics, and UHMW-PE are particularly suitable here. This ultra-high molecular weight polyethylene has already proven to be suitable in implants. This plastic has been used in knee and hip implants for over 20 years.

In many cases, there are also unclear findings regarding cancellous bone. In order to place an endosseous dental implant with improved safety in these cases without a prior bone build-up, a dental implant which prevents rotation during the time in which composite osteogenesis is built up is preferred. Such an anti-rotation lock can be created with an expansion body made of a resorbable and biocompatible polymer. This material should preferably have a degradation time of 3-9 months. These materials are tough and have sufficient ductility. Thanks to this choice of material, the endosseous dental implant can be placed in a single session in the above-mentioned findings.

However, the expansion body according to the invention can also be made from a medical steel, which has also been used for implants for a long time. However, the medical steel together with the titanium alloys, if these two components are in contact, cause a redox reaction. It is therefore proposed to provide at least those areas which are in contact with the screw sleeve made of titanium or the screw bolt with a coating which prevents the redox reaction. A gold coating is particularly suitable for this. In order to make the mobility of the expansion arms of the expansion body as mobile as possible, it is advantageous to make the wall thickness of the expansion arms increasingly radial in the radial direction from the connection point on the distal ring to their proximal ends. In addition, in order to further increase the mobility, it can be useful to provide the expansion arms of the expansion body with peripheral articulation points in the area near their connection points to the distal ring. Such peripheral articulation points can be designed in the form of molded notches.

The smallness of the expansion body itself limits the possible number of spreading arms evenly distributed over the circumference. The number of spreading arms is expediently between two and six. If the expansion body is made of plastic, the preferred number should be between two and four. However, if the spreader body is made of medical steel, a larger number of spreader arms will be provided in order to achieve sufficient mobility, preferably between three and six. The preferred choice of fine threads, by means of which the screw bolt can be screwed into the screw sleeve, generally makes sense that as a result there is as tight a connection as possible between the screw bolt and the screw sleeve, which achieves a bacterial blocking effect.

If the expansion body is made of medical steel, the choice of fine threads has the additional advantage that the forces required to expand the expansion arms are reduced.

BRIEF DESCRIPTION OF THE INVENTION [0013] In the drawing, a preferred embodiment of the subject matter of the invention is shown and described below with reference to the accompanying drawings.

[0014] The figures show:

1 to 3 show a preferred embodiment of the screw sleeve of the endosseous implant according to the invention, FIG. 1 showing a diametrical longitudinal section and FIG. 2 a perspective view of the screw sleeve with a view of its proximal end and FIG. 3 again a perspective view, this time with a view of the distal end , 4 to 6 4 show different views of the expansion bolt, FIG. 4 here showing a central longitudinal section, while FIG. 5 shows a perspective view of the screw bolt with a view of the distal end and FIG. 6 with a view of the proximal end of the screw bolt. 7 to 12 show different views of the expansion body of the endosseous implant according to the invention, always in the non-expanded state before installation, FIG. 7 showing a top view of the proximal end of the expansion body, while FIG. 8 is a side view and FIG. 9 is a diametrical longitudinal section along the line AA in FIG FIGS. 7 and 10 show a longitudinal section along the line BB in FIG. 7. FIGS. 11 and 12 both show a perspective view of the expansion body, in FIG. 11 in a proximal view and in FIG. 12 in a distal view. 13 to 16 the endosseous dental implant is shown in a first assembly phase, FIG. 13 showing this in a distal view, FIG. 14 in a side view, FIG. 15 in a diametrical sectional drawing and FIG. 16 in a perspective view. 17 to 20 show the endosseous dental implant in a second assembly phase, again with FIG. 17 a distal view, FIG. 18 a side view and FIG. 19 a diametrical section and FIG. 20 a perspective view.

Ultimately, the endosseous dental implant shows in the fully assembled state, whereby again

21 to 24, FIG. 21 a proximal plan view, FIG. 22 a side view, FIG. 23 a diametrical view

Longitudinal section and Fig. 24 shows a perspective view of the proximal end of the endosseous implants.

In the following description, the individual parts of the endosseous dental implant are first described individually, and the interaction of the individual parts is explained below using the various assembly phases.

1 to 3 show the screw sleeve of the endosseous dental implant. The screw sleeve mainly takes on the tasks that the hollow screw does for a conventional endosseous dental implant. However, in conventional endosseous dental implants, the hollow screw is longer than the screw sleeve, which is designated by 1 in total. This screw sleeve 1 has a distal area 6 and a proximal area 7. These terms are derived from the anatomy and mean here in the inserted state of the endosseous dental implant that the distal area is the area that extends from the center of the patient, in which the Dental implant is inserted, is removed, while the proximal region 7 is closer to the body center of the patient to whom the endosseous implant is inserted. This conceptual interpretation also applies to the other two main parts of the dental implant according to the invention.

The screw sleeve 6 has an external thread 2, which is usually rather sharp-edged and correspondingly achieves a thread in the cortical tissue when screwing into a predrilled hole in the jaw bone. The screw sleeve has an internal thread, which is designed as a fine thread. Fine threads are threads that have a much smaller pitch than a standard thread. The internal thread 3 serves for the exact infeed of the screw bolt 10, which will be discussed later. In the distal end region of the screw sleeve 1, this has a bearing surface 5. This bearing surface 5 is adapted to the abutment to be used. Since these abutments have different design variants, these bearing surfaces 5 are either absolutely flat or, as shown here, for example, with a rounded, conical bearing surface. Compared to the bearing surface 5, the wall thickness of the screw sleeve 1 is thickened in the proximal area 7. An annular section 8 is used for this purpose. This annular section 8 forms a support bracket 9. The fine thread is continuously molded into the screw sleeve 1 up to this support bracket 9. The annular section 8 is penetrated by an outlet bore 4 which is larger in diameter than the largest cross-sectional diameter of the conical part of the screw bolt 10. The screw sleeve 6 can be cylindrical or conical on the outside.

The screw bolt 10, which is shown in detail and alone in FIGS. 4 to 6, represents in principle a mixture of an Allen screw and a bolt. The screw bolt 10 has a head 11. This head 11 has a Larger diameter than the bolt portion 12. An external thread 13 in the form of a fine thread is attached to the head part 11. This external thread 13 corresponds in diameter and pitch to the internal thread 3 of the screw sleeve 1. The screw bolt 10 has an internal screw head drive, which can have a wide variety of embodiments, such as, for example, of the double-square, internal hexagon, line female, torque polydrive or torx type list the most common versions.

In the example shown here, the screw head internal drive is designated 14 and designed as a hexagon socket. The actual bolt portion 12 is conically shaped. It is directly connected to the head 11 with the largest diameter and tapers towards the proximal end 15. The largest diameter of the pin portion 12 is at least approximately the same as the largest inner diameter of the expansion body 20. In the area of the proximal end 15 of the pin portion 12, this is relative large chamfer 16 provided. This chamfering serves to facilitate the insertion of the screw bolt 10 into the expansion body 20.

7 to 12, the expansion body 20 is shown in different views. This expansion body consists of a distal ring 21 which is provided with a terminal collar 22. This terminal collar 22 has an outer diameter which corresponds to the inner diameter of the screw sleeve 1. The outer diameter of the distal ring in turn corresponds to the inner diameter of the outlet bore 4 in the screw sleeve 1. Four spreading arms 23 are formed on the distal ring 21 in the example shown here. In FIG. 9, the spreading body 20 is in a section along the line AA, as in FIG Fig. 7 shown. The distal ends of the spreader arms 23 align with the inner wall surface of the distal ring 21. This is most clearly seen in Fig. 9, which shows a section along the line A-A. Since in this embodiment the spreading body 20 is provided with four spreading arms 23, the section line A-A lies exactly between two adjacent arms. Only in this sectional drawing is only the distal ring 21 cut through, while the spreading arms do not lie in the cut surface. The spreading arms 23 are, so to speak, only visible along their side edge, which is relatively thin here.

In the sectional drawing B-B, which is shown in Fig. 10, a section rotated by 45 ° to the sectional area A-A is shown, and here the two opposite spreading arms 23 can be seen exactly in the middle in their thickest wall thickness on average. It can be seen here that the spreading arms initially have the same wall thickness as the wall thickness of the distal ring 21 and then gradually increase to approximately their proximal ends. The most complex design of the spreading arms 23 is shown most clearly in the two perspective representations in FIGS. 11 and 12.

11 shows the expansion body 20 with a view of the proximal side, while FIG. 12 shows a view from the distal side, so that one can see into the distal ring here. The cross section of the spreading arms 23 in the region of the proximal ends 24 can be seen in particular in the drawing according to FIG. 11. The long notched edges 26 directed radially outward are particularly striking. These notched edges 26 on the spreading arms 23 serve to penetrate into the cancellous tissue of the jaw bone in the spread state of the spreading arms 23. This is described in more detail with reference to the following figures.

A first assembly phase is shown in Figs. 13-16. FIG. 13 shows a top view of the proximal end of the endosseous dental implant in this first partial assembly, the screw sleeve 1 on the one hand and the expansion body 20 on the other hand being shown here. The expansion body 20 is shown with a view of the proximal end, the annular section 8 being recognized on the one hand and the proximal end of the expansion body 20 also being visible through the outlet bore 4. In the side view according to FIG. 14 it can be seen that the expansion body 20 has not yet been completely inserted into the screw sleeve 1. The bolt 10 itself has not yet been inserted into the expansion body 20. The introduction of the expansion body 20 into the screw sleeve 1 is achieved and facilitated by the conical bearing surface 5 for the abutment. The first introductory phase can easily be carried out by hand. The first phase of the assembly, shown in FIGS. 13 to 16, can be achieved by pushing the expansion body 20 into the expansion sleeve 1 with your finger. However, as soon as the expansion body with its distal ring 21 is practically pushed in to the level of the bearing surface 5 for the abutment, the expansion body can only be pushed further into the screw sleeve 1 with the aid of the screw bolt 10. This can be carried out until the position as shown in FIGS. 17 to 20 is reached. In this position, the spreading body 20 lies with its terminal collar 22 on the support bracket 9 of the annular section 8. The head 11 of the screw bolt 10 is now pressed in so far that the proximal end of the external thread 13 is in contact with the distal end of the internal thread 3. Now the screw bolt can be screwed in further with a screw tool which corresponds to the screw head internal drive 14 in the screw bolt 10. When the screw bolt 10 is screwed in further, the conical bolt portion 12 will penetrate into the expansion body 20 without initially pushing the expansion arms 23 radially outwards. However, the conical portion already presses the end collar 22 outwards and is deformed to such an extent that it deforms in a form-fitting manner with the internal thread 3 to form a form-fitting connection.

Although the possibility of assembling the endosseous implant by the dentist or orthodontist is described here, the implant according to the invention is preferably pre-assembled by machine and packaged and delivered in the position as shown in FIGS. 17 to 20, even the screw bolt 10 some turns are already screwed in.

In this position, which corresponds approximately to FIGS. 17 to 20, the endosseous dental implant is now inserted into the jawbone. In order to be able to carry out this screwing action, the external thread 2 must be inserted through the cortical tissue. In order to avoid premature spreading of the spreading arms 23, a separate screw, not shown here, can be used, which has the same screw head internal drive as the screw bolt 10, but has an enlarged head, which is either on the outside on the distal end of the screw sleeve abuts or is designed so that the screw head comes to rest positively on the bearing surface for the abutment. As soon as the screw sleeve 1 has been advanced through the cortical tissue, the screw sleeve 1 can be screwed in to its end position, then the auxiliary screw can be removed and the screw bolt 10 screwed in again and driven forward up to. the end position as shown in Figs. 21 to 25.

To prepare the setting of the endosseous dental implant, the orthodontist or dentist uses, as usual, a step drill or a correspondingly conical drill. The step drill has a first, proximal area which corresponds in depth and diameter to the expansion body 20 in the area of the expansion arms 23 before they are deformed. The distal step has a larger diameter, this diameter corresponds to the diameter of the screw sleeve 1.

In this way, the screw sleeve with the expansion body 20 can be fully inserted with little effort, and only then the screw 10 is advanced to its end position, as shown in FIGS. 21-25. Here, the spreading arms are spread outward and thereby reach an area which in turn corresponds approximately to the diameter of the screw sleeve 1, but only in its proximal end area. The notch edges 26 penetrate beyond the predrilled diameter into the cancellous tissue. As a result, pressure is exerted on the cancellous tissue, this is compressed, and after a relatively short healing time, an absolutely non-rotatable position of the expansion body 20 and thus also an absolutely non-rotatable position of the endosseous dental implant in the jawbone is achieved.

Thanks to this improved anchoring of the endosseous dental implant according to the invention, an improved anchoring is achieved which, in certain cases, eliminates the need for a previous bone build-up and the risk of loosening of the endosseous dental implant by micro-movements in the rotating direction is prevented.

Finally, it should be pointed out that it is also possible to introduce a small amount of natural bone substitute material, as is known for regenerative dentistry, into the bore already provided for placing the implant. With the endosseous dental implant according to the invention, this material is pressed into the cancellous tissue under a certain pressure before it hardens.

As already mentioned, the choice of material is important. Both the screw sleeve 1 and the screw bolt 10 are preferably made of titanium alloys. This material is well documented in dental implantology. However, the expansion body 20 is not suitable for being produced from titanium or titanium alloys, since this material is too hard and brittle and therefore elastic deformation is practically impossible. For this reason, the expansion body is preferably made of a biocompatible plastic, such as UHMWPE manufactured. This material can be easily processed on CNC machines and has the required elasticity. A particularly suitable biocompatible plastic for the expansion body consists of a resorbable polymer. Such a plastic can consist of polylactides, polygluconates, polydiaxanones or combinations thereof. These plastics can be machined, but can preferably also be processed by thermoplastic injection molding. For the preferred embodiment here, a PLA is used which has biodegradability, which allows the expansion body to be dismantled in a time of approximately 3-9 months.

But it is also entirely possible to manufacture this expansion body 20 from a medical steel, which is also easy to edit and has the required elasticity. Although there is also experience with dental implants made of medical steel, one has moved away from this material today in favor of titanium alloys. In itself, however, the screw sleeve and the screw bolt could also be made of medical steel. If the entire dental implant is made from this single material, there is no redox reaction. However, if a titanium alloy is used both for the screw sleeve and for the screw bolt, but a medical steel is used for the expansion body 20, a redox reaction naturally occurs. There are various coating options to prevent this redox reaction. A solution known particularly in medical technology is to apply a gold coating. A gold coating has the additional advantage that it does not trigger any allergic reactions.

If the expansion body (20) is made of medical steel, it is advisable to reduce the rigidity of the expansion arms (23) in the transition area from the distal ring (21) to the expansion arms by reducing the material wall thickness in this peripheral area of articulation points. The hinge points can be shaped by notches.

LIST OF REFERENCE NUMBERS

[0032]

threaded

external thread

Internal thread (fine thread)

outlet bore

Storage area for abutment distal area proximal area annular section

support bracket

bolts

head

bolt share

External thread (fine thread)

Internal screw head drive proximal end

chamfer

Spreading body distal ring terminal collar

Spreader arms proximal ends of the spreader arms

Cross-sectional area at 24

notched edge

Claims (14)

claims 1. Endosseous dental implant, comprising a screw-in part with an upper region (6) which is distal in the inserted state and a lower region (7) which is proximal in the installed state, the distal region (6) being designed with a bearing surface (5) which serves to support an abutment which can be fastened thereon, the screw-in part being cylindrical or conical on the outside and cylindrical on the inside and having an external thread (2) and an internal thread (3), characterized in that the screw-in part is a screw sleeve (1) which is open at both ends and whose internal thread (3) from the distal region (6) to a support console (9) leads to the fact that the endosseous dental implant further comprises an expansion body (20) which has a distal ring (21) with a terminal collar (22) and several which are formed proximally on the ring Has spreading arms (23), each with a lateral notch edge (26), and distant a spreading bolt (10) which can be inserted into the spreading body (20) and a distal head f (11) and a proximal conical bolt portion (12). 2. Endosseous dental implant according to claim 1, characterized in that the screw sleeve (1) and the screw bolt (10) is made of a titanium alloy. 3. Endosseous dental implant according to claim 1, characterized in that the expansion body (20) is made of a biocompatible and bioresorbable plastic. 4. Endosseous dental implant according to claim 3, characterized in that the expansion body is made of biocompatible and resorbable polymers, preferably polylactides, polyglucomates, polydiaxanones and combinations thereof, with a degradation time of less than 12 months. 5. endosseous dental implant according to claim 1, characterized in that the expansion body (20) made of a medical steel and at least those areas that are in contact with the screw sleeve (1) are coated to report a redox reaction. 6. Endosseous dental implant according to claim 1, characterized in that the coating is made of gold. 7. Endosseous dental implant according to claim 1, characterized in that the external thread (2) of the screw sleeve (1) is a sharp-edged thread suitable for anchoring in the cortical bone tissue. 8. Endosseous dental implant according to claim 1, characterized in that the internal thread (3) of the screw sleeve (1) and an external thread (13) on the distal head (11) of the expansion bolt (10) are each a fine thread. 9. Endosseous dental implant according to claim 1, characterized in that the screw bolt (10) is provided with an internal screw head drive (14). 10. Endosseous dental implant according to claim 5, characterized in that the expansion arms (23) of the expansion body (20) in the area near their connection points to the distal ring have peripheral articulation points. 11. Endosseous dental implant according to claim 5, characterized in that the articulation points in the peripheral area are formed notches. 12. Endosseous dental implant according to claim 1, characterized in that the expansion body has two to six spreading arms evenly distributed over the circumference. 13. Endosseous dental implant according to claim 1, characterized in that the wall thickness of the spreading arms increases in the radial direction from the connection point on the distal ring to its proximal ends. 14. Endosseous dental implant according to claim 1, characterized in that it is delivered in a preassembled state in which the expansion body (20) is pushed into the screw sleeve (1) to such an extent that the terminal collar (22) in the screw sleeve (1) rests on the support bracket (9) and the screw bolt (10) with the external thread (13) grips the internal thread (3). 22 21 23