ES1247211U - TRANSEPITELIAL PILLAR (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Transepithelial abutment for the union of a prosthesis with a dental implant, characterized in that it comprises three components: - an upper body, with an upper base and a lower base both connected by a through hole that has an internal thread, - a lower body, with an upper base and a lower base connected by an inner housing, said upper base presenting a surface around the opening of the housing and the housing presenting a seat to receive the head of a screw, and - a screw inside the hollow of the lower body with the screw head located above the seat, the upper body being integral with the lower body, with the lower base of the upper body inserted into the opening of the housing of the lower body, thus forming a single device. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Transepithelial abutment

OBJECT OF THE INVENTION

The present invention, transepithelial abutment, refers to a device used as a union between an implant and a dental prosthesis whose main purpose is to solve problems associated with the height and angulation of the prosthesis. Preferably, the transepithelial device or abutment is made of biocompatible material and is anchored and attached to the dental implant.

The field of application is that of dentistry and in particular to interface devices for fixing prostheses in dental implants, mounted on the upper and lower jaws, and on which the prosthesis is attached, which can be a crown or a structure dental, such as a bridge, or total dental prosthesis.

BACKGROUND OF THE INVENTION

Currently, dental implantology techniques allow the replacement of dental roots with dental implants made of biocompatible material, usually some titanium alloy, to which the corresponding artificial prostheses or dental pieces are attached.

In general, the phases of implantation of these implants are summarized in an initial phase of implant insertion, which is followed by a subsequent intermediate phase of osseointegration, which means a waiting time, until the last phase of fixation of the final prosthesis. .

Before the aforementioned definitive prosthesis is fixed, a provisional prosthesis can be placed on the implant as closely as possible to the definitive prosthesis, which will allow an early start-up with or without functional loads, but achieving an aesthetic function immediately.

Currently, the available techniques allow said union to be made, by means of union cement or screwed cement, which results in cemented prostheses or screwed prostheses, and in which standard prefabricated titanium abutments or prostheses made to measured by CAD-CAM procedures.

Although at present the surgical techniques in the insertion and positioning of the implant have improved remarkably, there are surgical guiding systems, with prior planning by radiographic CT-type methods, previously formed, to position the implant in the bone, the final position of the implant will always depend on the bone structure resulting from the osseointegration process and by the insertion positions, from antagonist to the implant placed, to inclined positions of the implant, which usually range from 0 ° to 45 °, the latter being the most unfavorable .

There will be a significant number of situations and it is impossible to have all the angled abutments manufactured in a standard way to solve all the inconveniences that arise in implant restorations using their corresponding prosthesis.

Of the prosthetic solutions, the transepithelial abutments are one of the most valued products among their users. These abutments, which act as a link between the implant and the dental prosthesis (complete prosthetics, crown or bridge), have different characteristics and advantages that allow improving precision and comfort in dental procedures, as well as avoiding possible complications for the patient.

Among the known techniques, the All-on-four technique stands out, which is an implant technique to solve complete arch treatments with only 4 implants and with the placement of a fixed prosthesis for the entire arch. the same or day of surgery. In this system, transepithelial abutments are normally used, combining angled and / or straight according to the required adaptation of the anatomy to the prosthesis to solve the cases that are detected.

The main objective of the present invention is, therefore, to develop a transepithelial abutment that allows correcting the position of the closure of the dental implant with the dental prosthesis in height and / or inclination between 0 ° and 45 ° with respect to the axis of the implant. .

EXPLANATION OF THE INVENTION

The present invention therefore relates to a transepithelial abutment, straight or angled, of a biocompatible material and with a direct connection to an endosseous dental implant, specially designed for use in both multiple prosthetic restoration and single crowns.

A first object of the present invention is, therefore, a transepithelial abutment according to claim 1. Said abutment comprises three components:

- An upper body, with an upper base and a lower base, connected by a through hole that has an internal thread, said hole serving for the introduction of a screw that will be threaded in said thread and as a passageway for a screwdriver to apply a tightening torque to a captive screw, which is part of the abutment, and which will serve to hold the abutment to the implant,

- A lower body, with an upper base and a lower base connected by an internal cavity that has a seat to support a head of said first screw, said body being integral with the upper part, and

- A captive screw, housed in the internal cavity of the lower body, between the upper body and the lower body, said first screw being placed in the housing before the joint assembly between the upper body and the lower body.

In accordance with the above, the transepithelial abutment object of the invention is composed of three components assembled in such a way that they form a single device.

Therefore, the transepithelial pillar is made up of two bodies joined in a way solidary and a screw, captive inside the two anterior bodies, as the third component component of the transepithelial pillar. The dental structure or prosthesis fits on the upper body, which is preferably connected to the abutment by a second screw, and the lower body is fitted and fixed directly on the implant with the help of the captive screw that is part of the abutment object of the invention. After mounting the abutment, that is, after introducing the captive screw inside the lower body and coupling or joining the upper body on the lower body, the three components form the same part, that is, a single device. For this, the union or coupling of the upper body on the lower body is carried out in such a way that it is permanent, that is, that both bodies are integral, preventing them from separating.

The transepithelial abutment object of the present invention is designed to be used in the upper or lower jaw and to support substitutions of dental pieces in order to restore masticatory and aesthetic function. These abutments in combination with endosseous implants are indicated for both multiple restorations and single tooth restorations.

Other additional characteristics of the present transepithelial abutment are:

- The transepithelial abutment allows angulations with respect to the axis of the implant from 0 ° to 45 °. For this, the lower body can have different configurations depending on the required angle of inclination. If the angle of inclination is 0 °, that is, there is no angle of inclination between the dental prosthesis and the dental implant, the hollow of the lower body is straight, that is, it has a single axis "a" that runs through the lower body from its upper base to its lower base. Said first axis "a" coincides with the axis of the dental implant when the abutment is connected to the implant. On the other hand, if the required angle of inclination is 45 °, the lower body has a gap that is not straight, and that is determined by at least two axes, a first vertical axis "a", in the lower part of the body. inferior and coincident with the axis of the dental implant when the abutment connects to the implant, and a second axis "b", in the upper part of the upper body, angled with respect to the first axis "a" and perpendicular to the upper base of the body The angle between the first axis and the second axis is the that determines the inclination of the abutment, and specifically the inclination of the upper body of the abutment. Depending on the required inclination, the lower body will present one configuration or another, that is, there will be as many lower bodies as necessary.

Accordingly, a first lower section of the hollow of the lower body extends along a first axis "a" and a second upper section of said hollow extends along a second axis "b" that forms an angle with respect to said first axis "a", said second axis "b" being perpendicular to the upper base of said lower body.

- The joints between the upper body and the lower body, preferably are of the type:

a) Friction fit between the two bodies that have complementary geometries,

b) Welding between the two bodies,

c) Thread between the two bodies, and

d) Fixing system between the two bodies of the cam mechanism type.

- The upper body of the transepithelial abutment can have two designs:

a) A design for bridges or complete prostheses that has a rotating base, and

b) A design for unitary pieces with an anti-rotational base, that fits with the dental structure, or dental prosthesis,

- The upper body thread, in combination with the upper lower body base, is used to place and attach other possible dental components to the abutment for the fixation of the dental prosthesis, such as a healing plug, a straight or dynamic abutment element , CAD / CAM structures, among others.

- The flat surface of the upper base of the lower body located around the opening of the hollow of the lower body, and concentric with the upper body, acts as a support surface, which is flat, with constant dimensions around the upper body, to enable better support of the prosthesis or dental structure on said abutment. Thanks to this support base with constant dimensions throughout the base provided by the upper part of the lower body, a better biological closure is achieved between the prosthesis or dental structure and the abutment thanks to a greater and better contact surface between the aforementioned elements. The components that fit into this transepithelial, in the upper body combined with the upper base of the lower leather, can be the same for all implant compatibilities depending only if it is for complete prostheses, bridges or single crowns.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to facilitate the understanding of the characteristics of the invention, a set of figures is attached as part of said description for illustrative and non-limiting purposes.

Figure 1 shows a sectional view of three examples of embodiment of the abutment object of the invention, angled in this case, and composed of the three components joined by: socket (A); welding (B); thread (C); and cam mechanism (D).

Figure 2 shows a perspective view of two exemplary embodiments of an angled abutment with the upper body and the lower body separated, the one on the left with an upper body with anti-rotary configuration and the one on the right with an upper body with rotary configuration.

Figure 3 shows the two pillars of figure 2 but joined.

Figure 4 shows a front view of an angled abutment object of the present invention, the one on the left rotating and the one on the right anti-rotating. In both examples, the support and closing surface concentric to the upper body is observed.

Figure 5 shows a side view of an exploded view of an angled abutment, in this case anti-rotary, with the three components.

Figure 6 shows a section of Figure 5.

Figure 7 shows a side view and a section of an angled abutment like that of Figures 5 and 6 but forming a single device and where the captive screw is observed.

Figure 8 shows a side view and a section of a straight pillar forming a single device where the captive screw is observed.

Figure 9 shows a sectional view of the transepithelial abutment object of the present invention placed on the dental implant and next to a screwdriver that allows the captive screw to be screwed into the implant.

Figure 10 shows a sectional view of the transepithelial abutment object of the present invention placed on the dental implant and an anatomical dental prosthesis of some bio-compatible material, zirconium type, obtained by CAD-CAM procedures, sintered metal part, re-machined or milling, in this case related to an interface part or TiBase, with its respective screw, interposed between the abutment object of the invention and the dental part, including a screwdriver in charge of screwing the screw of the metal part, or interface or TiBase, on the upper body of the pillar. In the example, the transepithelial abutment is angled, but it could also be straight.

Figure 11 shows a sectional view of the transepithelial abutment object of the present invention placed on the dental implant, with a dental prosthesis obtained by CAD-CAM procedures either by sintering, sintering with re-mechanization, machining and / or milling or by procedures of casting obtaining the prosthesis by traditional analog procedures, either for a definitive dental prosthesis or for a provisional dental prosthesis. Said prosthesis is attached to the transepithelial abutment object of the invention by means of a corresponding fixing screw with the anatomical dental piece, zirconium type or any biocompatible material (since they could be of different Cr-Cb, peek, gold alloy, tilite, ... materials), with the collaboration of a screwdriver to screw the dental piece to the transepithelial abutment using the aforementioned fixing screw. In the example, the transepithelial abutment is angled, but it could also be straight.

PREFERRED EMBODIMENT OF THE INVENTION

Next, and according to the previous figures, a detailed description of different embodiments of the invention is made.

Figure 1 shows four angled transepithelial abutments according to the present invention that are formed by three parts or components that are an upper body 20, a lower body 30 and a captive screw 40 between both parts. Likewise, the upper body 20 and the lower body 30 are preferably joined in one of the following ways:

- (A) by friction fit by the geometries between the two bodies that fit together,

- (B) by welding between the two upper lower bodies,

- (C) by internal or external thread between the two components, additionally using an adhesive to join both elements or

- (D) by cam fixing mechanism between both bodies.

After joining or coupling the upper body 20 and the lower body 30, the screw 40 remains captive inside the assembly formed by the two bodies and the three components form a single device or pillar. Both the upper body 20 and the lower body 30 are hollow and thus allow the screw 40 to remain captive inside them, between both bodies, mainly in the hollow inner housing of the lower body 30, preventing the upper body 20 from the screw 40 exit. This configuration gives rise to the transepithelial abutment object of the present invention.

Figure 2 shows an angled pillar on the left with the upper body 20, 25 separated from the lower body 30 prior to the coupling or union between the two. The pillar on the left has an upper body 20 with an anti-rotary configuration and the pillar on the right has an upper body 25 with a rotary configuration. This configuration mainly affects the arrangement of the prosthesis, unitary crown or dental element on the upper body 20, 25, so that if it is necessary for the prosthesis or dental element to move with respect to the upper body, a rotating upper body 25 will be provided and if an anti-rotational upper body should not be moved 20. Figure 3 shows the two pillars of figure 2 but assembled, coupled or joined together in a solidary way, forming the pillar or single device that is the object of the present invention.

Figure 4 shows a front view of two angled pillars, the one on the left with an anti-rotating upper body 20 and the one on the right with an upper body 25. It can be seen as the upper body, in any of its two preferred forms , it has an upper opening or chimney and a thread 21 inside to place and connect with a screw other possible dental components through said upper body 20, 25. In this figure it can also be seen how the lower body 30 has a geometry lower 31 which will depend on the type of dental implant to which the abutment is to be connected. The thread 41 of the screw 40 protrudes inferiorly, which is located captive inside the lower body 30 and its movement is limited by the upper body 20, 25.

It is also observed how the lower body 30 presents in its upper base 70 a concentric surface to the upper body 20, 25. This upper base 70 also acts as a support base where the dental structure or possible dental components that are attached to the abutment rests, maintaining said base 70 its geometry and the same width throughout its perimeter to ensure that said prosthesis or dental components have a constant and balanced support that will result in a better seating of said components on the abutment.

The lower part of the lower body 30, located below the upper base 70 will also depend on the implant to which the abutment is to be attached, since said lower part of the abutment will be fixed to the maxillary or mandibular implant since it is inserted in the same. Therefore, the design of this lower body 30 will vary according to the type of implant to be used, and also the screw 40 will also depend on the type of implant. It can be seen how the screw 40 remains captive inside the lower body 30 respecting the upper opening or chimney 26 of the pillar arranged in the upper body 20, 25.

Figure 5 shows a side exploded view of the components of an angled abutment, in this anti-rotational example, object of the present invention. Specifically, an angled lower body 30 is observed, a screw 40 inserted in the lower body 30 and an upper body 20 that is arranged on said lower body 30, thus forming a single device or pillar.

The transepithelial abutment allows angulations with respect to the axis of the implant of between 0 ° to 45 °, depending mainly on the configuration of the lower body 30, for which said lower body can have different configurations depending on the required angle of inclination. In the case of the example, where the upper body has an inclination of approximately 30 ° with respect to a vertical axis "a", which coincides with the axis of the implant, the lower body has a gap that is not straight, and which is determined by at least two axes, the first vertical axis "a", coinciding with the axis of the dental implant when the abutment connects with said implant, and a second axis "b", angled with respect to the first and perpendicular to the upper base 70 of the body lower 30. The angle formed by the first axis "a" with the second axis "b" is what determines the inclination of the pillar, and specifically the inclination of the upper body 20 of the pillar. Depending on the inclination required by the pillar, the lower body 30 will have one configuration, that is to say, there will be as many lower bodies as there are inclinations necessary, for which the inclination of the axis "b" will be varied with respect to the axis "a". The angle between both axes can vary between 0 ° and 45 °.

Figure 6 shows a section of the angled pillar of figure 5, specifically a pillar with its three components:

- an upper body 20, with an upper base 23 and a lower base 24 connected both by a through hole 26 having an internal thread 21, - a lower body 30, with an upper base 70 and a lower base 33 connected by an inner housing 38, with a seat 37 and a recess 36, said upper base 70 presenting a surface around the opening of the housing 38 and presenting a seat 37 inside the recess of the housing to receive the seat 41 of the head a screw 40 whose thread 42 is arranged in the recess 36 of the housing 38, and

- a captive screw 40 located inside the housing 38 and the recess 36 of the lower body 30 with the head of the screw 40 located above the seat 37 to rest on it. The thread 41 of the screw will probably protrude through the lower base 33 of the lower body 30, although it will depend on the dimensions of the lower body 30 and the recess 36 thereof, as well as the length of the screw 40.

The lower base 24 of the upper body 20 is inserted into the housing 38 of the lower body 30 so that by means of different joining means 50 both bodies will be joined together and the screw 40 will be held captive between them, supporting the head seat 41 of the screw 40 on the seat 37 in the recess 36 of the lower body 30.

Figure 7 shows a side view of an angled abutment object of the invention and a section of said side view. In them you can see the three components of the abutment.

On the other hand, figure 8 shows a side view of a straight pillar also object of the invention and a section of said side view. Unlike the previous angled abutments, in this example, there is no angle of inclination between the dental prosthesis and the dental implant, the hollow 36 of the lower body being straight, that is, it has a single axis "a" that runs through the body from its upper base 70 to its lower base 33. Said axis "a" coincides with the axis of the dental implant when the abutment is connected to the implant. The rest of the characteristics are common to those of an angled abutment such as those described above. That is, the upper body 20 could be anti-rotational, as shown, or rotary. The housing 38 and hollow 36 of this pillar are preferably cylindrical.

In view of the above, it is observed that the upper bodies 20 do not depend on the lower body 30 and that regardless of the angulation of said lower bodies 30, the upper body 20 may incorporate a rotary or anti-rotary configuration 25.

Figure 9 shows a section of an angled abutment object of the invention connected on a dental implant 90 with the help of a screwdriver 80 responsible for screwing screw 40 into the internal thread 91 of implant 90. For connecting the abutment on the implant , the lower part of the lower body 30 is placed inside the implant 90, matching the outer end 31 of the lower body 30, whose geometry depends on the implant, and subsequently the thread 42 of the screw 40 is screwed into the thread 91 of the interior of the implant 90. The head 41 of the screw 40 is accessed through the recess 26 of the upper body 20, which is crossed by the screwdriver 80. A dental prosthesis can be placed directly on the upper body 20 (for example, by cementation) which it will rest on the upper or support base 70 of the lower body 30, surrounding said upper body, or provide another dental device, such as an interface that acts as a connection between e the abutment and the prosthesis, but also leaning on the support base 70. This support 70, where the dental structure or other possible dental components rests, maintains its geometry keeping the same surface around its perimeter, so that in this way it has greater support in future structures and complementary components that are installed on the abutment, improving biological closure and the distribution of the different chewing loads of the dental structure arranged on the abutment and towards the implant.

The angle of inclination of the angled abutment can vary between 0 ° and 45 ° depending on the needs, so that there will be a transepithelial abutment for each required inclination, that is, an angled abutment with 25 ° where the angle between the axis "a ”And the“ b ”axis is 25 °, a 15 ° angled abutment where the angle between the“ a ”axis and the“ b ”axis is 15 °, or a 40 ° angled pillar where the angle between the axis "a" and axis "b" is 40 °. There will be as many pillars, and more specifically as many lower 30 bodies, as angulations are required.

To attach the screw 40 of the transepithelial abutment to the implant 90 in those cases in which the lower body 30 presents an angle between both axes "a" and "b", it will be It is necessary to use a screwdriver that allows to act on the screw with said inclination.

Figure 10 shows an abutment object of the invention on which an intermediate dental element 95, or interface, is arranged, which is fastened to the upper body 20 of the abutment object of the invention through a screw 96 that is screwed into the thread 21 inside the hollow 26 of the upper body 20. On said intermediate dental element 95 the prosthesis or dental piece P is arranged. Said intermediate dental element 95 rests completely on the support base 70 with a surface of constant dimensions around the upper body 20 The clamping screw 96 of the intermediate element 95 is screwed with a screwdriver 80 that can be tilted between 0 ° and 30 ° between the axis “b” and the axis “c” of the screwdriver. In this way, the maximum correction value would be the sum of the following two angles, the angle between the axis "a" and the axis "b", corrected by the abutment object of the invention, up to 45 °, and the angle between axis "b" and axis "c", corrected by the intermediate element, or interface, 95 to 30 ° (which will depend on the type of interface), being therefore the resulting angle of correction, in this case, between 0 ° and 75 °. According to the above, and according to the description of the invention, the angle between axis "a" and axis "b" can be 0 °, so that the pillar would be straight, on which a part can be connected dental with an interface that can also be straight, so that the screwdriver 80 can only act at 0 ° (the “c” axis of the screwdriver coincides with that of the transepithelial abutment and that of the implant), or be like that of the previous example, that is, it allows the inclination of the screwdriver 80.

Figure 11 shows another example in which the dental piece, or dental prosthesis P, in which the dental piece or structure P, manufactured by CAD-CAM, fits and rests directly on the support base 70 of the base upper body 20, 25 of the pillar with angled or straight lower body 30, object of the invention, fixing the prosthetic assembly 95 with a screw 96 on the pillar object of the invention, specifically, screwing said screw 96 onto the upper body 20 of the pillar object of the invention. The fastening screw 96 of the intermediate element 95 is screwed with a screwdriver 80 which in this case, due to the configuration of the prosthesis 95, can correct an inclination as in the previous example, that is, up to 45 ° by the abutment Transepithelial object of the invention plus up to 30 ° by CAD-CAM structure, is that is, between 0 ° and 75 °, with respect to the axis of the implant that coincides with the vertical axis "a" of the abutment. As in the previous case, the lower body 30 of the abutment may be angled, as in the example, or it can be straight.

Claims (10)

1. Transepithelial abutment for the union of a prosthesis with a dental implant, characterized in that it comprises three components: - an upper body, with an upper base and a lower base both connected by a through hole that has an internal thread, - a lower body, with an upper base and a lower base connected by an inner housing, said upper base presenting a surface around the opening of the housing and the housing presenting a seat to receive the head of a screw, and - a screw inside the hollow of the lower body with the screw head located above the seat, the upper body being integral with the lower body, with the lower base of the upper body inserted into the opening of the housing of the lower body, thus forming a single device. 2. Pillar, according to claim 1, characterized in that the upper base has a surface of constant dimensions. 3. Pillar, according to any of the preceding claims, characterized in that the upper body is attached to the lower body with permanent joining means. 4. Pillar, according to claim 3, characterized in that said joining means can be friction fit between the two bodies, or by welding between the two bodies, or by thread plus an adhesive between the two bodies, or a cam fixing mechanism. 5. Abutment, according to any of the previous claims, characterized in that the screw remains captive between both bodies. 6. Pillar, according to any of the preceding claims, characterized in that the upper body has a rotary or ante-rotational exterior configuration. 7. Abutment, according to any of the preceding claims, characterized in that the lower part of the lower body has an external configuration adapted to the implant in which it is to be installed. 8. Pillar, according to any of the preceding claims, characterized in that the hollow of the lower body extends along a first axis "a". 9. Pillar, according to claim 8, characterized in that a first lower section of the hollow of the lower body extends along said first axis "a" and a second upper section of said hollow extends along a second axis "b "Which forms an angle with respect to said first axis" a "and is perpendicular to the upper base of said lower body. 10. Abutment, according to claim 9, characterized in that the angle between the first and second axis can be between 0 ° and 45 °.