SCREWED ANGLED PEG

Abstract

The present Utility Model refers to a new functional perspective applied to the prosthetic component called “SCREWED ANGLED TRUNNION” developed in light of the need to enable screw-fastening of dental prostheses be they unitary or multiple; characterized by applying an inner thread in its upper part, which may be made of grade 1, 2, 4, and 5 titanium or else made of any other material as may be used in the creation of dental prosthesis components, whereby enabling a further choice in the form of coupling the implant fixed thereto, and may be manufactured for CM, EH and IH fittings or any other fitting forms as may be developed, promoting and facilitating the maintenance process thereof in view of the possibility of threading, contributing to reduce the build-up of residues and consequently reducing the possibility of inflammation at the base of the implants.

Claims

1. An angled trunnion capable of fastening a prosthesis by screwing.

2. The angled trunnion according to claim 1 comprising an angled inner thread applied to its upper part.

3. The angled trunnion according to claim 1 comprising a a Morse Taper fitting, an External Hexagon fitting, or an Internal Hexagon fitting options.

4. The angled trunnion according to claim 1 capable of fastening the prosthesis by gluing or cementing.

5. The angled trunnion according to claim 2 comprising a Morse Taper fitting, an External Hexagon fitting, or an Internal Hexagon fitting.

6. The angled trunnion according to claim 2, wherein the angled trunnion is capable of fastening the prosthesis by gluing or cementing.

7. The angled trunnion according to claim 2, wherein the angled trunnion is capable of fastening the prosthesis by gluing or cementing.

8. The angled trunnion according to claim 3, wherein the angled trunnion is capable of fastening the prosthesis by gluing or cementing.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0014] The “SCREWED ANGLED TRUNNION” can be made with the MT (Morse Taper), EH (External Hexagon) and IH (Internal Hexagon) fitting, as described in FIGS. 7, 8 and 9, which cross-sectionally shows the assembly sequence of the “SCREWED ANGLED TRUNNION” up to the positioning for fitting the implant, for these systems, which are the ones most used today, among others.

[0015] Its bottom base is manufactured such that it can be adapted to the type of implant utilized (CM, EH and IH), the form of fitting the “SCREWED ANGLED TRUNNION” in the implant may be produced such that it makes the prosthesis element on the implant rotational or anti-rotational. Its diameters are relative to the laying platforms of the implants, which may be commercialized in the following sizes: 3.5 mm; 4.0 mm; 4.5 mm and 5.0 mm, which are the most common, and may also adapt to other platform diameters as may be needed and/or developed.

[0016] The thread of the fastening screw of the “SCREWED ANGLED TRUNNION” on the 3.5 mm platform implants may be M1.8 and for 4.0 mm and 5.0 mm implants they may be M2.0, these being the sizes most utilized, though they may vary according to each project.

[0017] Some reasons are essential in analyzing the option for a “SCREWED ANGLED TRUNNION” when compared to the cemented angled trunnion and will be explained ahead.

[0018] After placing/performing maintenance on the prosthesis, the need may arise to make certain adjustments, for example: replace the prosthesis, or some prosthesis element. A screwed prosthesis enables replacement by simple withdrawal of the screws and replacing the already repaired element. When the prosthesis is cemented, the difficulty to repair is much greater, and furthermore may lead to the loss of the prosthetic element, as mentioned previously.

[0019] Another important benefit of the screwed prosthesis, is the decrease in the risk of losing the implant by contamination. During the process of cementing or any other type of gluing, this cement or glue may penetrate into the region of the soft tissue (gums), and may induce inflammation and consequently cause the loss of the implant.

[0020] Other notable characteristics of the “SCREWED ANGLED TRUNNION” are: [0021] Easy maintenance of the prosthesis elements on the implants installed and in visualizing the implants already installed; [0022] Decrease in the build-up of residue of biological material on the soft tissue which ultimately prevents inflammation, swelling and the potential loss of the implant; and [0023] Multifold aesthetic improvements.

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] We shall now describe the prosthetic component called “SCREWED ANGLED TRUNNION” for improved understanding as a whole:

[0025] FIGS. 4, 5 and 6 present, according to variations of the fittings (CM, HE and IH), side view of the “SCREWED ANGLED TRUNNION”, indicated by the Details “A”, “B” and “C” the place of the position of the “inner thread”, being the site where the prosthesis will be screwed.

[0026] FIGS. 7, 8 and 9, describe the assembly sequence on the MT (Morse Taper), EH (external hexagon) and IH (internal hexagon) implants and in FIGS. 10, 11 and 12 the cross-sectional view of the internal profile and the profile view of the angled trunnions already screwed in each one of these systems.

[0027] The coupling of the prosthesis to the “SCREWED ANGLED TRUNNION” is shown in the assembly sequence in FIGS. 13, 14, 15 and 16. The assembly example used was of the prosthesis in the prosthesis elements, the MT (Morse Taper) fitting, for example. Any other systems could be used for said assembly.

[0028] FIG. 13 shows a multiple prosthesis in coupling position, with the use of two SCREWED ANGLED TRUNNIONS and already coupled to the SCREWED ANGLED TRUNNIONS in FIG. 14.

[0029] FIG. 15 shows a unitary prosthesis in coupling position to the “SCREWED ANGLED TRUNNION” and already coupled to the “SCREWED ANGLED TRUNNION” in FIG. 16.

[0030] As already mentioned, “THE SCREWED ANGLED TRUNNION” is made of grade 1, 2, 4, or 5 titanium, and can also be produced of any other material as may be used in a dental prosthesis component in the production process. The main difference in relation to the angled trunnions used is the existence of an “inner thread” in the upper part of the trunnion, as described in FIGS. 4, 5 and 6 detail “A”, “B” and “C” respectively. All these drawings show the inner thread in the upper part for “THE SCREWED ANGLED TRUNNION”, where the prosthesis (tooth or set of teeth) will be screwed as described in the assembly sequence in FIGS. 7, 8, and 9. Although the development of the inner thread is the object of the Utility Model patent now filed, “THE SCREWED ANGLED TRUNNION” still has its previous function, if necessary, which is the cementing/gluing of the prosthesis. What is offered in the present Utility Model is the possibility of screwing the prosthesis (tooth or set of teeth), with the applications already described above.

[0031] The process of choosing and placing the prosthesis element begins once the implant is placed and in accordance with the choice of the specialist who may await bone bonding of the implant before installing “THE SCREWED ANGLED TRUNNION” or place it on the same day as the implant. In FIGS. 10, 11 and 12, the details “D”, “F” and “H” show the implant (where “THE SCREWED ANGLED TRUNNION” will be coupled) and “THE SCREWED ANGLED TRUNNION”, per se with the details (details 1, 2 and 3) where the prostheses will be coupled to the prosthesis elements which in this case is “THE SCREWED ANGLED TRUNNION”.

[0032] In FIGS. 10, 11 and 12, the details “E”, “G” and “I” cross-sectionally illustrate how the prosthesis element (“THE SCREWED ANGLED TRUNNION”) is coupled to the implant in the three systems most used, namely Morse Taper (MT), FIG. 1, External Hexagon (EH), FIG. 2 and Internal Hexagon (IH), FIG. 3. FIGS. 13, 14 and 15 illustrate how the prosthesis is coupled to the prosthesis elements which in this case is “THE SCREWED ANGLED TRUNNION”.