RU2622377C2 - Screw implant for jaw bone with coronal compression thread and apical self-tapping thread - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: screw implant for a jawbone with a coronal compression thread screw with threads and an apical self-tapping thread with threads, thread pitches are substantially identical. Compression thread is apically adjacent to the implant coronal head thread for the final placement at least in the cancellous bone to which the cutting thread is apically adjacent for the final placement at least in the apical cortical bone medium. Core diameter and the outer diameter of compression thread at least in its apical region varies conically with narrowing from the coronal portion to the apical portion. The axial length of compression thread varies mainly from the two- to fifteen +/-25% values of the cutting thread axial length. Radial depth of the cutting thread depth exceeds the radial depth of compression thread in the apical part, preferably by 1.5 +/-25%. Angle (β) of the compression thread wedge exceeds the angle (α) of the cutting thread wedge, preferably by 1.5 +/-25%.

EFFECT: invention can reduce the screwing power to increase not only the time before the first load application after implantation due to high primary implant stability, but also to strengthen the retention and stability after the implantation period, the implant can be used in immediate loading protocols.

21 cl, 6 dwg

Description

The invention relates to an implant for a jaw bone with a coronal compression thread and an apical self-tapping thread according to the restrictive part of independent claim 1 of the formula.

In documents DE 3918309 C2 and EP 0320740 B1 (Bauer K.S.I.) a screw implant for the jaw bone with compression thread is disclosed, the core and shell of which are tapered from the coronal to the apical end and the core between the threads of the thread is concave. Thanks to the concave threads of the thread, the bone substance remains between them. Thus, fixation of the implant in the cancellous bone is achieved as a result of continuous radial compression of the bone substance during the screwing of the conical screw implant, and the implant can be relatively heavily loaded immediately after implantation, without the need to wait for its engraftment. DE 391 8309 C2 further discloses that the ratio of the angles of the cone of the outer shell and the angles of the cone of the core is from 1.177 to 1.666.

DE 202011001474 U1 (Biomed) discloses a screw implant for the jaw bone, which has one or two self-cutting threads, which, after screwing the implant into the distal and, under certain conditions, proximal cortical bone. Due to the radially relatively high thread threads of the axial geometric closure, fixation of the implant in the cortical bone is mainly achieved. In this case, before the application of a relatively strong load, the engraftment phase should end, after which, however, the implant can be loaded more heavily than the aforementioned Bauer implant.

DE 10251469 A1 (Brasseler GmbH) discloses a screw implant for the jawbone with three different thread portions in the endoossal region, the apical thread portion having a large nominal profile height with steep side walls, the middle thread portion has a conical core and a cylindrical curved generatrix and coronal thread section trapezoidal thread with a small nominal height profile. Three sections of the thread at the same time have approximately the same length.

DE 202007004943 U1 (Champions-Implants GmbH) discloses a screw implant for the jawbone with two different portions of the thread in the endosseous region, the apical portion of the thread being a self-cutting conical compression thread and the coronal portion of the thread being a conical micro-thread, both cones tapering to the apical the end.

U.S. Pat. No. 5,588,838 A (Hansson and Holmen) discloses a screw implant for a jawbone with two different thread portions in the endoossal region, wherein the apical thread portion is a self-cutting cylindrical cutting thread and the coronal thread portion is a conical micro-thread that tapers towards the apical end.

DE 69017349 T2 (= EP 0424734 B1) (Vrespa) discloses a screw implant for the jawbone with two or three different portions of the thread in the endosseous region, the apical portion of the thread being a conical triangular cutting thread, the middle portion of the thread being tapered, but the outer diameter of the cylindrical trapezoidal thread and the coronal portion of the thread is again a self-cutting cylindrical cortical thread.

DE 10356920 B4 (Lippe) discloses a screw implant for the jawbone with three different thread portions in the endoossal region, wherein the apical thread portion is a self-cutting cylindrical cutting thread, the middle thread portion is a non-cutting cylindrical compression thread and the coronal thread portion is a self-cutting cylindrical cortical thread moreover, between the cortical thread and the compression thread there is a step of diameter, as well as between the compression thread and the apical cut her thread.

In the document EP 1527749 A2 (Lippe) a screw implant is disclosed, very similar to the implant disclosed in DE 10356920 B4, however, it does not provide for a stepwise transition between the threaded sections. The heart-shaped and outer diameter of the cutting thread and compression thread can also go to the top on a cone.

All of the screw implants mentioned immediately after implantation, as well as after the engraftment period, show more or less good stability in the jawbone, however, the loads are excessively high and the screw implant loosens or even completely falls out. Moreover, it is precisely in the case of a cylindrical or weakly conical compression thread that the twisting forces are relatively large, therefore there is a great risk of rupture in the region of smallest diameter, therefore, for example, in the neck region between the coronal region and the first threaded section or directly in front of the apical threaded section.

The objective of the present invention is to eliminate these disadvantages and the development of the corresponding restrictive part of the screw implant based on the above-described prior art EP 1527749 A2 so that the likelihood of unscrewing is reduced, that the resistance to stress both immediately after implantation and after the engraftment period is increased and that the engraftment period is shortened .

The problem is solved by means of an invention characterized by the features of independent claim 1, with preferred embodiments disclosed in the dependent claims.

It is important that the axial length of the compression thread is at least twice +/- 25% of the length of the cutting thread, so that the radial depth of the cutting thread is greater than the radial depth of the compression thread 4, preferably 1.5 times +/- 25% and that the wedge angle of the threaded threads of the compression thread be larger than the wedge angle of the threaded threads of the cutting thread, preferably 1.5 times +/- 25%.

Due to this, an advantage is achieved that both screw-implant fixation forms, known per se, are used, firstly, due to the compression closure of the cancellous bone substance by compression thread and, secondly, by providing a geometric closure of the incision into the substance cortical bone self-carving. Subjected to compression compression bone material, therefore, is first cut by a cutting thread, and then compressed. This ensures better compression while reducing the screwing force. After passing the spongy bone, the cutting thread penetrates into the opposite cortical layer. Easy fixing takes place there thanks to the good cutting properties of the apical cutting thread.

The advantage of the feature that the axial length of the compression thread is approximately equal to twice +/- 25% of the axial length of the cutting thread is that the compression thread is completely immersed in the cancellous bone substance and the cutting thread is completely immersed in the cortical bone substance, which ensures the optimal combination force and geometric closure in the spongy and cortical bone substance. As a result of this, the implant can be subjected to a very large constant load immediately after implantation.

The advantage of the feature that the maximum external diameter of the compression thread is less than the cutting thread, preferably 1.2-2 times +/- 10%, is that the cutting thread cuts the bone during insertion and then fixes in the cortical layer. The bone substance cut by the cutting thread, but still connected, is subsequently again compressed by the compression thread, stabilized and compacted. This makes it easier to compress the bone substance, so less manual force should be used when screwing in the implant. The diameter of the cutting thread should be larger compared to the compression thread, at least at least in the lower apical region of the latter. Due to this difference in thread diameters, the likelihood of unscrewing is reduced.

It is preferable that the maximum external diameter of the compression thread in the cross part is larger than the external diameter of the cutting thread, preferably 1.2-2 times +/- 10%.

The advantage of the feature that the maximum external diameter of the compression thread is larger than the cutting thread, preferably 1.2-2 times +/- 10%, is that screwing the implant is much easier, without causing too large wounds, which leads to a shortening of the period engraftment. In addition, the substance cut by the cutting thread, but still connected by the periphery of the bone, is subsequently compressed by the compression thread and stabilized. The bone near the implant, therefore, is repeatedly damaged by this implant, which (surprisingly) has such a positive effect on the stability of the implant that no initial remodeling is possible for a long time. Thus, the implant remains initially firmly fixed for a longer period of time, i.e. the period of time before the prosthetic overlay of the tire (bridge) is significantly extended. This is a huge advantage, as sometimes prosthetics by the dental laboratory cannot be performed in a timely manner, which increases the risks of loosening the implants.

The advantage of the feature that the radial depth of the cutting thread is greater than the radial depth of the compression thread 4, preferably 1.5 times +/- 25%, is that due to this, radial and vertical precompression of the cancellous bone occurs already during screwing of the implant. substances with a cutting thread with a smooth surface, therefore, the compression thread with a rough surface, the spongy bone substance should be compressed much less, which contributes to a much easier screwing implant.

An advantage of the feature that the angle of the wedge of the threads of the compression thread is greater than the angle of the wedge of the threads of the thread, preferably 1.5 times +/- 25%, is that, thereby, the cutting thread axially leaves in place a spongy bone substance that then the compression thread shifts, resulting in a very large axial geometrical closure.

Preferably, the implant material is round-concave between the threads of the compression thread, so that an optimum radial compaction of the spongy bone material is achieved as a result. However, other concave shapes may be provided between the threads of the compression thread.

Preferably, the compression thread is coated and / or treated with a surface enhancing and roughening agent, thereby increasing adhesion friction and improving blood adhesion. For hygienic reasons, the cutting thread does not have this surface roughness and preferably on the surface is smooth, in particular polished. This feature is particularly preferred because the implant according to the invention is selected, as a rule, such that the cutting thread is in the opposite cortical layer or protrudes somewhat from this cortical layer, for example, into the maxillary sinus or nasal cavity.

Preferably, after implantation, the coronal region of the compression thread is located in the coronal material of the cortical bone, due to which, although slight, radial compression can occur in the coronal material of the cortical bone, and thereby fixation is improved. However, the entire compression thread can, after the implantation, remain completely in the cancellous bone material, so that the neck of the implant is relatively free in the cortical bone material, because the main fixation takes place with the compression thread in the cancellous bone material and the cutting thread in the apical cortical bone material . Of course, between the implant neck and the compression thread, another, for example identical to the apical cutting thread, coronal cutting thread could be provided to create additional geometric closure in the coronal material of the cortical bone.

Preferably, a threaded region is provided between the compression thread and the cutting thread, which is cylindrical or conical and has the same diameter or the same taper as the regions before and after it. This threadless region serves only for more convenient manufacturing of the implant, since it clearly delimits both threaded areas and thereby can carry out separate technological operations, in particular, for surface treatment. The compression thread should be as rough on the surface as possible, and the cutting thread should be as smooth as possible.

Summarizing the above, we can state the following.

The implant has a compression thread in the area that is located in his jawbone, which is joined by a self-cutting sharp thread that penetrates into the opposite cortical region. This sharp thread should not have surface enhancers, as there are situations (the surgeon cannot control this) when the thread is screwed through the opposite corticalis, for example, into the lower wall of the nasal cavity or maxillary cavity. It would be a drawback if the thread were roughened because the indicated areas are dirty / non-sterile. The roughened parts of the implants would contribute to the preservation of infections there. Rough parts in the bone contribute to good adhesion to it.

This implant therefore has two completely different forms of fixation: lateral compression of the bone occurs in the conical region (this is known), while cortical fixation takes place in the cortical region. The advantage is a very high primary stability and the fact that both forms of fastening are used.

The implant shown here is made integrally with the head. The invention, however, is not limited to whole implants; conventional two-element implants may well be so performed in the endoossal region.

Surprisingly, in a thin place between the threads to prevent rupture of the implant, a diameter of 1.8-2.2 mm is sufficient, for example, during installation.

In one particularly preferred embodiment, the cutting thread is remote from the compression thread (and in this case they are connected to each other by a relatively thin portion) and the thread of the cutting thread has an increasing diameter on both sides (top and bottom). The maximum diameter of the cutting thread is in the middle of the thread. This embodiment has a particular advantage in that the unscrewing of the implant is prevented. Since the cortical layer is displaced when screwing the thread. It returns to its original place as soon as the thread penetrates deeper and a smaller diameter of the thread or a thin connecting section are in the cortical layer.

The invention is illustrated by drawings, which represent the following:

FIG. 1 is a radial view of a screw implant according to the invention;

FIG. 2 is a schematic illustration of FIG. one;

FIG. 3 is an axial view of FIG. 2 from the apical direction;

FIG. 4 is an axial view of FIG. 2 from the coronal direction;

FIG. 5 is an enlarged view of FIG. 1 in the field of compression thread;

FIG. 6 is an enlarged view of FIG. 1 in the field of cutting thread.

In FIG. Figures 1 and 2 show a screw implant 1 according to the invention, a once actual transverse general view (Fig. 1) and once in a schematic image (Fig. 2) with schematically drawn threads 4 and 6 with their invisible and external envelopes. Invisible lines are also drawn in the head 2 of the implant.

An implant neck 3 is adjacent to the coronal head 2 of the implant, adjacent to the compression thread 4, followed by a transition region 5, which passes into the cutting thread 6, ending at the end 7 of the implant.

The implant head 2 conically pointed in the coronal direction has, according to FIG. 4 three recesses 8 displaced along the shell relative to each other by 120 ° to fix an unimaged denture or supporting structure for this. In this case, the implant head 2 has an axial length of 7.2 mm and a cone of approximately 10 ° between the outer diameter of 2.65 mm to 3.91 mm.

From the neck 3 of the implant in the apical direction, the screw implant 1 has a conical core, which is approximately rotationally symmetrical about the longitudinal axis A.

Next in the apical direction, the neck 3 of the implant forms a narrowing between the head 2 of the implant and the compression thread 4, in this case has a length of 3 mm and decreases in diameter from 3.91 mm at the head 2 of the implant 2 to 2.3 mm in the middle 3 of the neck of the implant , then again increases to 3.7 mm for compression thread 4, and the transitions are rounded. The compression thread following the apical direction has an axial length of 15.2 mm and is tapered sharply in the apical direction from an external diameter of 3.7 mm to 2.5 mm, which corresponds to a cone angle of about 4.92 °. The heart-shaped diameter of the compression thread 4 varies equivalently to the outer diameter and has a depth of 9 threads of about 0.52 mm, and the pitch 10 of the thread is about 1.5 mm (figure 5). Between all adjacent triangle-shaped threaded threads 11a-11j (FIG. 1), circular recesses 12 with a radial depth of 0.75 mm (measurement from the outer diameter) are provided on the core, which extend in height to the peaks 18a, 18b, and an average angle is formed wedge β = approximately 60 °. This significantly improves, in particular, the axial compression of the spongy bone. The vertices 13a, 13b (Fig. 5) on the outer shell of the threaded threads are rounded 0.05 mm.

The next threaded region 5 in the apical direction extends again by 1.5 mm and decreases with rounding from an external diameter of 2.5 mm for compression thread 4 to 1.5 mm.

The next cutting thread 6 in the apical direction has a length of 3 mm and rises from an external diameter of 1.5 mm to 3.55 mm, then decreases over 1.3 mm to 3.4 mm and again to an external diameter of 1.5 mm. In this case, the cutting thread 6 has a cone angle with a narrowing in the apical direction of about 3.58 °, which, however, due to the short length, can be seen only with a difference in diameters of 0.15 mm. The diameter of the core of the cutting thread 6 varies equivalently to the external diameter and has a depth of thread 14 of about 0.875 mm, the pitch 15 of the thread being 1.5 mm (FIG. 6). Between all two adjacent threads of threads 16a and 16b having a triangular shape (Fig. 1) on the cylindrical core there is respectively a round-concave recess 17 with a radial depth of 1.75 mm (measurement from the outer diameter), the side faces of the thread 16a themselves 16b, however, are straight and form a wedge angle α = about 40 °. This significantly improves, in particular, axial compression of the spongy bone. The vertices 18a, 18b (Fig. 6) on the outer surface of the threaded threads are not rounded, but have a knife sharpness with an axial width of about 0.03 mm.

The implant end 7 following the apical direction has a length of 1.5 mm, an external diameter of 1.4 mm and an apical chamfer of 0.68 mm.

The shape of the threaded threads 11a to 11j of the compression thread 4 approximately coincides with the shape of the threaded threads 16a, 16b of the cutting thread, namely a triangular one. However, there is a difference in that the threaded threads 16a, 16b of the cutting thread are axially steeper (wedge angle α = about 40 °) and radially deeper (about 1.5 times) compared to axially flatter (average wedge angle β = 60 °) and radially less deep compression threads 11a, 11b. This contributes to easier screwing of the implant 1 and compression of the substance of the cancellous bone and in the axial direction, which is still not known in the prior art.

As for the height of the cutting thread, the following can be noted.

The height of the thread (axial length) of the cutting thread 6 is always the same (i.e., it does not depend on how long the part of the implant 1 that is in contact with the bone is long), preferably the height of the cutting thread 6 is 1.5-4 mm, while the endoossal compression portion of the compression thread 4 may have a length of 4-20 mm.

This is due to the fact that this part of the cutting thread 6 should only reach and pass the opposite cortical layer, this cortical layer almost always has the same thickness, regardless of how high the alveolar tuber is, into which then part of the compression thread 4 of implant 1 is implanted.

In principle, it is sufficient if this cutting thread 6 in the opposite cortical layer is 0.5-1 mm. Since, however, the rough compression thread should always be completely immersed in the bone (otherwise the rough part would fall into the mucous membrane or even the oral cavity and then bacteria would develop on it, and this would lead to inflammation) and since the exact length implant 1 often cannot be precisely determined in advance, the length of the cutting thread 6 is desirable from 1.5 to 4 mm, so that the surgeon can maneuver and can correctly install the implant or correct the planning error.

Regarding the width of the threads, the following can be noted.

In a particularly preferred embodiment, the cutting thread 6 is wider than the widest place of the compression thread: for example, the cutting thread 6 may have a width of 5.5-7 mm for use in the rear of the upper and lower jaws, while the compression thread 4 has a maximum diameter 4-4.5 mm. Under this condition, the following occurs: a cutting thread 6 cuts a bone during insertion and then is fixed in the cortical layer. Cut by cutting thread 6, but still connected, the bone substance is then again compressed and stabilized by compression thread 4 and compacted. It should be noted that for such an implant a core hole is created with a diameter of 2 mm, then a cutting thread 6 with a diameter of, for example, 5-7 mm is introduced, and the core of the compression thread (with a nominal diameter of maximum 4.1 mm) has a thickness of, for example, 3 , 6 mm. The process is comparable to sandblasting: after all, there is also not only removal, but also the surface is compacted.

Since the cross of the cortical layer is highly mineralized, it may be advantageous if the cross of the thread of the thread in the implant according to the invention is replaced by micro-threads or micro-grooves known per se. These structures, while providing benefits, can be smooth in the upper (close to the abutment) to avoid colonization by bacteria.

It is particularly preferable in comparison with the prior art in this implant that the rough compression thread 4 in conjunction with a tapering thread in both directions reliably prevents the unscrewing and further screwing of the implant 1. It has unexpectedly turned out that the implant according to the invention even with very small fractions of the threads very high screwing forces, which indicates a high primary stability. This stability is higher than both partial thread stability, which was proved in the experiment.

Screwing force for a structurally identical compression screw (13 mm endoossal length) without apical cutting thread: 50 Ncm.

Screwing force for cortical screw (only apical cutting thread, 3 mmh): 30 Ncm.

Screwing force of a compression and cutting screw according to the invention (13 mm endossal length; plus 3 mmh): 140 Ncm.

The implant design according to the invention is not limited to a one-piece implant: multi-element implants can also be used, which consist of an endosseous implant body and an abutment connected to it.

Claims (21)

1. A screw implant (1) for the jawbone with a coronal compression thread (4) with threaded threads (11a - 11j) and an apical self-cutting thread (6) with threaded threads (16a, 16b), the thread steps (10, 15) in which basically the same, with the compression thread (4) apically adjacent to the coronal head (2) of the implant for final placement, at least in the cancellous bone, to which the cutting thread (6) apically adjacent for final placement, at least in apical cortical bone substance, moreover, as a diameter core, and the external diameter of the compression thread (4), at least in its apical region, changes conically with narrowing from the coronal to apical part, characterized in that the axial length of the compression thread (4) is mainly from two to fifteen + / -25% of the value of the axial length of the cutting thread (6), and the radial depth (14) of the cutting thread is greater than the radial depth (9) of the compression thread (4) in the apical part, preferably 1.5 times +/- 25%, while the angle (β) thread wedge (11a - 11j) compression thread s (4) is greater than the angle (α) of the wedge screw thread (16a, 16b) of the cutting thread (6), preferably 1.5 +/- 25%. 2. A screw implant according to claim 1, characterized in that the maximum external diameter of the compression thread (4) is equal to or less than the external diameter of the cutting thread (6), preferably 1.2-2 times +/- 10%. 3. A screw implant according to claim 1, characterized in that the maximum external diameter of the compression thread (4) in the cross part is larger than the external diameter of the cutting thread (6), preferably 1.2-2 times +/- 10%. 4. A screw implant according to any one of paragraphs. 1-3, characterized in that the diameter of the core and / or the outer diameter of the cutting thread (6), at least in its apical region, tapers conically in the direction from the coronal to the apical. 5. A screw implant according to any one of paragraphs. 1-3, characterized in that the diameter of the core and / or the outer diameter of the cutting thread (6) in its coronal region narrows conically in the direction from apical to coronal. 6. Screw implant according to any one of paragraphs. 1-3, characterized in that the diameter of the core and / or the outer diameter of the cutting thread (6) in its apical region tapers conically in the direction from the coronal to the apical. 7. A screw implant according to any one of paragraphs. 1-3, characterized in that the minimum diameter of the core of the compression thread (4) is mainly +/- 10% of the maximum diameter of the core of the cutting thread (6). 8. The screw implant according to any one of paragraphs. 1-3, characterized in that the angle of the cone of the diameter of the core and the outer diameter of the compression thread (4), as well as the cutting thread (6) are equal and, in particular, are in the range mainly from 3.5 to 5 ° +/- 10%. 9. A screw implant according to any one of paragraphs. 1-3, characterized in that the angle of the cone of the diameter of the core and the outer diameter of the compression thread (4) are equal and, in particular, are mainly 5 ° +/- 25%, and the angle of the cone of the core and the outer diameter of the cutting thread (6) are equal and, in particular, make up mainly 3.5 ° +/- 25%. 10. A screw implant according to any one of paragraphs. 1-3, characterized in that between the threaded threads (11a - 11j) of the compression thread (4), a rounded-concave recess (12) is made with a diameter of 0.75 mm +/- 25%. 11. A screw implant according to any one of paragraphs. 1-3, characterized in that between the threaded threads (16a, 16b) of the cutting thread (6), a rounded-concave recess (17) is made with a diameter of 1.75 mm +/- 25%. 12. A screw implant according to any one of paragraphs. 1-3, characterized in that the surface of the compression thread (4) is rough, and the surface of the cutting thread (6) is smooth. 13. A screw implant according to any one of paragraphs. 1-3, characterized in that the coronal region of the compression thread (4) is located in the spongy cortical bone substance or in the crural bone substance after implantation. 14. A screw implant according to any one of paragraphs. 1-3, characterized in that between the neck (3) of the implant and the compression thread (4) there is a coronal cutting thread, in particular identical to the apical cutting thread (6), which after implantation is located in the coronal cortical bone substance. 15. Screw implant according to any one of paragraphs. 1-3, characterized in that between the compression thread (4) and the cutting thread (6) there is a threadless region, which is made cylindrical or conical and has the same diameter and correspondingly the same cone angle as the area immediately before and after it. 16. A screw implant according to any one of paragraphs. 1-3, characterized in that in the upper part of the compression thread, the thread is made in the form of micro-threads or has circular micro grooves. 17. A screw implant according to any one of paragraphs. 1-3, characterized in that the endosseous implant body and the abutment are made in the form of two different parts, and these parts are made with the possibility of screwing or gluing. 18. A set of screw implants (1) according to any one of paragraphs. 1-15, characterized in that the axial lengths of the cutting thread (6) for all screw implants (1) of the kit are basically the same and are in the range mainly from 1.5 to 4 mm, and the axial lengths of the compression thread (4) for screw implants (1) of the kit differ step by step by at least 2 mm and are in the range from 4 to 20 mm. 19. The kit according to claim 18, characterized in that in the upper part of the compression thread, the thread is made in the form of micro-threads or has circular micro grooves. 20. The kit according to p. 19, characterized in that at least part of the micro thread or micro grooves does not have an increase in surface. 21. Set according to any one of paragraphs. 18-20, characterized in that the endosseous implant body and the abutment are made in the form of two different parts, and these parts are made with the possibility of screwing or gluing.

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