• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Highly self-tapping dental implant system with cone-type hybrid connection and interspersed rails, which allows a high insertion torque (or disinsertion) and a parallel double cone block between the implant, the prosthetic abutment and the internal screw, even in its execution diameter 3.0 mm and gives the whole a great stability both primary and secondary, an excellent seal thanks to the double sealing of the cones, as well as a predictable fixation of the dental prosthesis on the implant in the long term. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2663539A1
    申请号:ES201700798
    申请日:2017-12-05
    公开日:2018-04-13
    发明作者:Julián CUESTA GARCIA
    申请人:Julián CUESTA GARCIA;
    IPC主号:
    专利说明:



    DESCRIPTION
    HIGHLY SELF-THROUGH DENTAL IMPLANT SYSTEM WITH
    hybrid connection and parallel double cone lock between the abutment
    5 PROTECTIC. THE IMPLANT AND THE INTERNAL SCREW.
    SECTOR OF THE TECHNIQUE
    The present invention relates to a dental implant. Enter the sector of oral implantology.
    BACKGROUND OF THE INVENTION
    Currently, in the world of Implantology, 15 times tend to be shortened by optimizing processes. Implants are placed immediately after the extraction of the dental piece, whether they are single pieces or complete archways, and at the same time the patients demand the supported prosthesis on the implants that have just been placed (immediate loading).
    These types of treatments have their advantages and disadvantages: On the one hand, if the load 20 received by the bone through the implant does not cause a micromotion of more than 150 microns in it, a higher quality bone joint will be achieved, at the same while the maturation of soft tissues is a clear advantage over the conventional protocol.
    But if the implants are few, small, their design does not dissipate mechanical stress well, or they move with the occlusal load, we will have serious problems.
    As a rule, the literature says that no immediate loading protocol should be made on implants placed with a torque of less than 30 Ncm, since below that figure of insertion torque, primary stability is considered to be poor.
    30 In Implantology, two different types of stability are contemplated:
    Primary, a purely mechanical concept, and relative to the greater or lesser resistance to movement of a newly placed implant and totally or partially surrounded by bone.
    Secondary or definitive, which is the one obtained when the implant already has
    also a biological union with the bone, after about two
    2

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    months of implantation.
    For this purpose, there is a study by Dr. Paolo Trisi published in The International Journal of Oral & Maxillofacial Implants 2011; 26: 837-849, titled High versus Low Implant Insertion Torque: A Histologic, Histomorphometric, and Biomechanical Study in the Sheep Mandible. This is a comparative study of the same implants introduced in sheep jaws whose previous osteotomy varied in terms of narrow or wide.
    In narrow osteotomies, the torque applied when introducing the implant was 110 Ncm on average, with spikes of 150 Ncm., While in wide ones, the implants were introduced with an average torque of 30 Ncm, considered as the ideal standard in The current state of the art. It studies primary and secondary stability, as well as physiological and histomorphometric changes week by week, during the first six weeks.
    The conclusions of this study say the following:
    11 The results of the present study showed that a high insertion torque of the implant (up to 150 Ncm) in dense cortical bone, in a protocol of no load, does not induce bone necrosis or implant failure, but instead increases stability primary and secondary implants, which is very relevant when carrying out immediate loading processes.
    Primary stability showed a marked reduction 7 days after implant placement, and one month later was necessary to achieve new stability from the neoformed bone (secondary) .11
    It is known that primary type stability is lost due to bone resorption of cells immediately in contact with the implant, and in turn, slowly but progressively, biological union is gained so that in the end the resulting stability is a whole mechanical-biological The biological ascending curve has been accelerated thanks to the rough surfaces of microscopic texture capable of retaining fibrin filaments and causing what is called contact osteogenesis, in which the first layer of new colonizing bone cells are installed on the implant and from there they also proliferate in the opposite direction, towards the bone they come from.
    But this way of improvement is limited, and hardly the biological stability of the implant will be important before a period of 6 weeks, since we will always be obliged to wait for biology, which we cannot change.
    On the other hand, we can act in the section of mechanical primary stability,
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    by modifying the implant design. The idea is to get an implant that is inserted with high torque, and that achieves stability levels much higher than usual without damaging the surrounding bone.
    With this invention, we will be able to start from a very high initial initial stability, so that even during the period of bone resorption, and even having logically lost part of it due to this phenomenon, we will still have a lot of stability, and it will be enough for The implant is maintained at all times below 150 microns critical of movement against any external force.
    At the same time, the threaded spiral passage far apart from the implant body will dissipate occlusal forces considerably better than a classic cylindrical design.
    The implant will be more stable, both before shearing and occlusal forces, thus allowing us to undertake complicated surgical situations with more guarantees of success.
    The fact that the implant has been designed for special situations does not mean that it does not behave equally well in more usual conditions, because it will always have more stability than a classic cylindrical one, even after osseointegration. This is due to two factors: first because with this invention the bone will be more overlapped around the implant and secondly because we will have a higher percentage of bone implant contact, due to the greater torque in its insertion. As can be seen from Dr Trisi's study, implants placed with high torque also have better secondary stability, since they achieve better osseointegration.
    At the same time, the wide space created between the turns allows a better vascularization and nutrition of the bone, this being very important in the narrow spaces.
    Among the factors to consider in immediate mechanical stability (primary) are:
    1. - Bone quality: The higher the bone density, in general the easier it will be to achieve stability.
    2. - Length and width of the implant appropriate to each situation.
    3. - Implant design: It is the most important factor, and at the same time, the only parameter on which we can act.
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    4.- Insertion Torque: Greater torque equal to greater stability, as long as the implant penetrates the bone, and does not turn on itself or compress it excessively or break it. It is directly related to the design of the implant, both in its external form and in the connection.
    Before a certain situation, of a certain bone quality, and once the implant of a suitable size (length and diameter) has been chosen, the great difference will lie in the design of the implant when it comes to achieving a greater or lesser degree of mechanical stability, essential if we want to undertake simultaneous placement in different complex situations:
    a) Post-extraction implementation
    b) Maxillary sinus lift
    c) Crest widening
    d) Guided bone regeneration processes
    e) Very porous bones, type III and IV.
    But even in normal situations, this invention will always provide us with more advantages:
    1. - It will guarantee a better bone-implant contact during the osseointegration process, which implies a higher quality of osseointegration (higher percentage of bone-implant contact, which is technically defined as BIC) and, consequently, greater implant survival at long term,
    2. - It will prevent micromotions that can alter this process (less osseointegration failures).
    3. - Greater mechanical implantation of bone-implants, even after osseointegration.
    4 - Better vascularization and nutrition of the surrounding bone, important in small spaces.
    Having a high Primary Stability is, therefore, essential for the osseointegration of the implant, in any clinical situation, whether it is at risk (as mentioned above) or not. The more complicated the situation (those mentioned above), the greater the difficulty of achieving it, but the greater the need to obtain it.
    Immediate loading protocols are now in high demand by the patients themselves as it prevents them from going through a few months of transience in the prosthesis that
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    They are very uncomfortable.
    Extraction of the dental piece with simultaneous implantation and sometimes also with immediate loading included are procedures that have many adherents, since if they are done correctly, they provide greater bone implant contact, and a greater long-term implant survival rate.
    There are multiple studies in the literature in which it is concluded that a non-excessive load is beneficial in terms of osseointegration quality and tissue maturation compared to the conventional protocol.
    Cases of entire arches with simultaneous placement of 4 or 6 implants, subsequent placement of titanium abutments with intraoral welding and immediate provisional or definitive prostheses are increasingly frequent and demanded.
    If we reduce the number of implants necessary for a complete rehabilitation, hygiene is better and the risk of periimplantitis is reduced, but the burden to be borne by each of them is greater. Hence, an appropriate implant design, which dissipates the loads in the bone, is very important. From the increasingly widespread use of all these risk procedures that shape current implantology, there is a need to design an implant system specifically designed for this purpose, which facilitates and ensures these processes. The need to design an implant system with which it is easy to obtain high primary stability in an easy and predictable manner is thus evident.
    First premise:
    It is necessary that the implant be placed with a high insertion torque:
    To achieve this, it is essential to modify the classic implant design, both of its external part and of the connection.
    Second premise:
    It is essential that it is extremely self-tapping, so that it does not block or turn on itself.
    Third premise:
    The connection must be able to withstand without problems that high torque that we are going to apply, without denting and without the conveyor being blocked in the implant.
    An important feature is the fact of providing this implant at its apex with a four-blade propeller with an extremely sharp edge.
    Most implants on the market are not self-tapping, or they are so
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    very slight, with blunt apexes, little sharp turns and cylindrical bodies nothing progressive. And they are often accompanied by connections that suffer plastic deformation beyond 70 or 80 Ncm.
    This combination of little self-tapping implant / cylindrical body / large diameter / weak connection is the most unfavorable, since during the insertion the implant can be blocked, and when trying to unlock it, the connection is rounded and we will be forced to use a forceps to its extraction.
    The invention serves to avoid all these problems.
    Another great advantage inherent in the design is the fact that the bone is more imbricated in the implant, entering and hugging it throughout its perimeter, which provides even greater mechanical stability compared to a conventional cylindrical implant, due to the better load distribution. This is valid both before and after osseointegration.
    This system allows to achieve excellent stability in three different ways:
    1. Only with its apical part inserted in the bone: Most of the so-called immediate implants only contact in its apical third or middle third.
    2. Only with its coronal part inserted: It would be the case of a sinus lift with simultaneous placement.
    3. Only with its intermediate part inserted: For example, in sine elevations in which in addition to growing inside it, we increase the height of the remaining crest; or in guided bone regeneration procedures with intermediate stabilization of the implant.
    Once the stability of the implant in the bone is achieved, the next step is the stability of the prosthesis in the long term, that is, the reliability of the Connection.
    A big problem that we face in daily practice is the loosening of the abutment screw with the consequent movement of the abutment-crown assembly. This is especially relevant in unit implants, and especially in those that replace molars, due to the high shear forces they have to withstand. The maximum expression of this problem is those unit implants that replace molars and are located as the last of the arch, whether it is superior or inferior. To avoid this loosening we have devised a novel parallel double cone lock.
    Another problem that we face more and more often in the clinic is the need to remove implants that are osseointegrated, either because they are bad.
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    positioned or affected by periimplantitis. This invention allows us the important advantage of being able to remove them without the need to tremble, because the novel connection allows the application of a high reverse torque, being able to remove the implant in an atraumatic way and preserving the bone.
    EXPLANATION OF THE INVENTION
    The invention is a very self-tapping implant that penetrates the bone in a very progressive manner, which in turn is internally provided with a connection that allows a high insertion torque to be applied without generating blockages of the insertion key and which also serves to block the prosthetic abutment thanks to the friction created by two parallel cones, that of the abutment on the implant and that of the screw on the abutment.
    The external shape of the implant is composed of a progressive conicity core (1b) and different for each implant size, which in turn is surrounded by very sharp turns (1c) and separated from it, which begin at the most apical part by a four-blade propeller (1d) and then they become progressively wider towards the occlusal and approximately half the length of the implant they undergo a split (1e), providing the implant with an added vertical anchor. Said propeller twists as we ascend towards the occlusal face of the implant, forming four oblique evacuation channels (1f). Regarding the connection (fig.2), it is a hybrid type: A cone between 5 and 6 degrees (2a) intermingles with 6 vertical rails (2c) that form a hexagon similar to a torx connection.
    In the connection there are three distinct zones, described from top to bottom, with the following characteristics:
    a) A first part, approximately 1 mm formed by a pure cone (2a).
    b) A second, hybrid zone, shared between the extension of the cone and the beginning of the vertical tracks, which is also approximately 1 mm long (2b).
    c) The third zone, lower, is exclusively composed of vertical tracks that make up a hexagon type torx that serves as indexation of the abutment and transmission of torque, and also measures approximately 1 mm (2c).
    This hybrid connection allows the hexagon mechanical platform to be wider, and therefore, supports more torque, and at the same time gives more stability to the implant-abutment assembly. This novel feature allows us the great advantage of being able to
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    Remove the implant already osteointegrated by applying reverse torque in case of implants improperly placed or affected by periimplantitis, without trefining and keeping the bone minimally invasive, which greatly facilitates the clinician's work and improves future treatment.
    Another advantage of this hybrid configuration is the fact that it greatly facilitates the output of the print coping from the implant, since to index it it is not necessary to reach the lower third of the connection, it is enough that the coping enters the hybrid zone .
    This fact is particularly important in the measurement of cases with very inclined and divergent implants, such as the increasingly common in All in Four, All in S / x type restorations, tuberosity implants, large bone vestibularization, etc. .
    Another innovative feature of this system is that the extractor thread of the abutment (fig. 6) is at the height of the screw head (6a), and not at the height of the hexagon, as is usual in the market. This gives us the great advantage of being able to lock and unlock the rotating pillars whenever we want, an action that would not be possible without this location of the extractor thread, this greatly facilitates the parallelization of the pillars, both in the mouth and in the laboratory model.
    Another novelty of this implant is the conical settling of the screw (9a with 6b) on the abutment, which is parallel to the conical settling of the abutment on the implant (5a with 2a), constituting a novel system of parallel double cone settling (13a and 13b).
    The first great advantage of this parallel double cone configuration is the fact that the implant-formed assembly (fig. 12) - abutment (fig. 11) - screw (fig. 10), behaves as a whole, withstanding stress mechanic and distributing it much better.
    The other great advantage of this parallel conical settlement is that the friction created by the screw on the abutment (13a) prevents loosening of the same, thus solving one of the great daily problems in clinical practice.
    Another novel feature of this abutment screw, apart from its conical settlement,
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    is that it has an hourglass shape with thinning in its middle part (9b), which facilitates its entry into the crown in cases of angled access chimneys (anterior sector).
    This hourglass shape causes the implant-abutment-screw assembly to flex without deformation in the face of a large load, having as the epicenter of flexion precisely the area of thinning of the screw (9b).
    The system has two platforms, narrow NP “narrow platform” (fig. 14) for the system versions with a narrow diameter implant (3.0 mm, 3.25 mm and 3.5 mm) and wide SP “standard platform” (fig. 15) for System versions with wide diameter implant (4.0 mm and larger). , The length of both connections is the same and the cone angles too. Only the width and depth of the tracks (2c) vary, which are greater in the wider connection.
    Another novelty that improves the technique is that the double cone provides the system with a double sealed seal.
    The protocol of placement of this implant consists of making a conical osteotomy staggered to the total length corresponding to the implant, in which the body of the implant, also conical, is only slightly longer, to allow the sharp turns to enter the adjacent bone , generating stability without damaging it, cutting and not crushing, thus preserving maximum cellular activity and physiology.
    In the case of facing a very hard bone, the so-called type I, the cone of the osteotomy must be slightly wider.
    BRIEF DESCRIPTION OF THE DRAWINGS
    To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is attached as an integral part of said description, where illustrative and non-limiting nature has been represented. next:
    Figure 1.- Elevation of the implant in a possible embodiment in terms of size and length.
    Figure 2.- Elevation of the implant section and its wide connection, standard platform (SP).
    Figure 3.- Perspective of the implant and its external shape.
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    Figure 4.- Implant apex.
    Figure 5.- Elevation of the abutment in a possible embodiment for wide connection, standard platform (SP).
    Figure 6.- Abutment section for wide connection (SP)
    Figure 7.- Apical view of the wide connection abutment (SP)
    Figure 8.- Section of the wide connection screw SP Figure 9.- Elevation of the wide connection screw (SP)
    Figure 10.- Section elevation of the wide connection screw (SP)
    Figure 11 Elevation of the wide connection abutment section (SP)
    Figure 12.- Elevation of the wide connection implant section (SP)
    Figure 13.- Section of the assembled assembly of a possible embodiment of the "implant-abutment-screw" system of wide connection (SP)
    Figure 14.- Elevation of the implant section in a possible embodiment of narrow diameter (03.0 mm) and its narrow connection, narrow platform (NP)
    Figure 15.- Elevation of the implant section in a possible embodiment of wide diameter (0 equal to or greater than 4.0mm) with its wide connection (SP)
    Figure 16.- Elevation of the implant in a possible embodiment of narrow diameter (03.0 mm) of narrow connection (NP).
    Figure 17.- Section elevation of the narrow implant (03.0 mm) with its narrow connection (NP)
    Figure 18.- Implant perspective in a possible embodiment of narrow diameter (03.0 mm)
    Figure 19.- Narrow diameter implant apex (03.0 mm)
    Figure 20.- Elevation of the narrow connection abutment (NP)
    Figure 21.- Elevation of the section of the narrow connection abutment (NP)
    Figure 22.- Apical view of the narrow connection abutment (NP)
    Figure 23.- Elevation of the narrow connection screw (NP)
    Figure 24.- Narrow connection screw section (NP)
    Figure 25.- Section of the narrow connection abutment (NP)
    Figure 26.- Section of the narrow connection implant (NP)
    Figure 27.- Section of the assembled assembly of a possible embodiment of the “implant-abutment-screw” system
    The invention can be carried out in various sizes in terms of implant length and diameter. Without this enumeration intended to be limiting, they may be made in sizes of 0 3.0 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15.
    In sizes from 0 3.25 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15.
    In sizes 0 3.5 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 10 and L15, L17.
    In sizes from 0 4 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15, L17.
    In sizes of 0 4.5 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15, L17.
    15 In sizes from 0 5 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15, L17.
    In sizes of 0 5.5 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and L15, L17.
    In sizes from 0 6 with the following lengths: L 7, L 8.5, L 10, L 11.5, L13 and 20 L15, L17.
    In diameters 3.0, 3.25 and 3.5 the connection will be in its narrow version NP "narrow platform" (fig. 14), and in the larger diameters the connection will be standard SP "standard platform" (fig. 15).
    25
    权利要求:
    Claims (9)
    [1]
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    1. Three-piece dental implant system: implant, abutment and screw (fig. 13), specifically designed to achieve very high primary and secondary stability in the bone-implant joint in a predictable and simple way, as well as a prosthesis stability Long-term loosening test, characterized by:
    - An external part of the implant body (fig. 1) formed by a very progressive conical core with variable taper depending on the diameter and length (1b), which is surrounded by very sharp turns and separated from the core both in the direction horizontal as vertical (1c).
    - An internal part consisting of a blind hole with two elements: a hybrid type connection and a female thread on which the abutment screw sits (fig. 2).
    - A prosthetic abutment (fig. 5) with a conical seat on the implant that avoids the loosening of the prosthesis through an optimal distribution of the forces and a friction block.
    - A conical set screw (9a) on the abutment, which tightens it on the implant blocking it.
    [2]
    2. Dental implant according to claim 1, characterized in that it comprises in its external form a quadruple propeller very sharp in its apical part (1d).
    [3]
    3. Dental implant according to claims 1 and 2 characterized in that it comprises four oblique cutting channels that start from the four-blade propeller and rise up to half the length of the implant and serve as an escape route and distribution of the bone chip produced during insertion (1f).
    [4]
    4. Dental implant according to claims 1, 2 and 3 characterized in that the thread turns have a progressive widening of the cutting edge that undergoes a half-length implant (1e).
    [5]
    5. Dental implant according to claim 1 characterized in that the set screw is shaped like an hourglass especially thinned in its center
    (9b).
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    [6]
    6. Dental implant according to claim 1, characterized in that the hybrid type connection (cone-rails), approximately 3 mm long, is formed by a cone (2a) and six vertical rails forming a hexagon (7a) torx type , which intermingle in its central part, or hybrid zone (2b). Forming approximately 1 mm of pure cone, 1 mm in its central part of hybrid zone and 1 mm of pure tracks (2c).
    [7]
    7. Dental implant according to claims 1 and 6, characterized in that the connection rails measure approximately 2 mm in total length between its pure hexagonal shaped part (2c) and its hybrid part between hexagon and cone (2b), and they support a torque of 100 Ncm of insertion or disinsertion without suffering plastic deformity in its closest connection.
    [8]
    8. Dental implant according to claim 1 characterized in that its abutment has an internal conical settlement (6b) for the screw that tightens it (9a) and another external parallel to the previous one (5a) that joins with the implant (2a), forming a parallel double cone lock (13a, 13b), with double sealing.
    [9]
    9. Dental implant according to claims 1 to 8 characterized in that the abutment thread of the abutment (6a) is located at the head height of the screw once the assembled assembly and not at the height of the abutment hexagon.
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    同族专利:
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    US20160270833A1|2013-11-05|2016-09-22|University Of Florida Research Foundation, Inc.|Articles comprising reversibly attached screws comprising a biodegradable composition, methods of manufacture thereof and uses thereof|
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    DE102006005705A1|2006-02-08|2007-08-16|Ilja Beilin|Implant system has slots that are made under upper edge of internal cone of implant for tool to ensure utilization of full length of conical surface|
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    FR2972625B1|2011-03-15|2014-02-28|Biotech Internat|DENTAL IMPLANT|
    法律状态:
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    ES201700798A|ES2663539B2|2017-12-05|2017-12-05|Highly self-tapping dental implant system with hybrid connection and parallel double cone block between the prosthetic abutment, the implant and the internal screw.|ES201700798A| ES2663539B2|2017-12-05|2017-12-05|Highly self-tapping dental implant system with hybrid connection and parallel double cone block between the prosthetic abutment, the implant and the internal screw.|
    PCT/ES2018/000086| WO2019110854A1|2017-12-05|2018-12-03|Highly self-tapping dental implant system with hybrid connection and parallel double cone locking between the prosthetic post, the implant and the internal screw|
    KR1020207016970A| KR20200086336A|2017-12-05|2018-12-03|Highly self-tapping dental implant system with prosthetic abutment, hybrid connection between implant and inner screw and parallel double cone locking|
    EP18886636.2A| EP3721829A4|2017-12-05|2018-12-03|Highly self-tapping dental implant system with hybrid connection and parallel double cone locking between the prosthetic post, the implant and the internal screw|
    US16/769,023| US20200330191A1|2017-12-05|2018-12-03|Highly self-tapping dental implant system with hybrid connection and parallel double cone locking between prosthetic abutment, implant and internal screw|
    CA3084899A| CA3084899A1|2017-12-05|2018-12-03|Highly self-tapping dental implant system with hybrid connection and parallel double cone locking between prosthetic abutment, implant and internal screw|
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