Multifunctional prosthetic component and its method of use

Abstract

In one aspect, a multi-use prosthetic component is provided. In certain examples, the component comprises a prismatic head, external marks and internal hexagon for indexing, fitting and orientation of the assembly. In another aspect, a dental implant system is provided, where in certain examples the system includes a covering cylinder, a plastic cover, a set screw and an implant with an external hexagon, which allows for, in addition to the function as a conventional assembler, capturing the implant in the packaging, shipping and installation in the bone tissue, application of torque, impression coping, a prosthetic pillar indexed to the implant device, and 3D orientation during surgery.

Claims

1. A multifunctional prosthetic component comprising: a prismatic head having one or more smaller faces and one or more larger faces; one or more grooves below the prismatic head; a prosthetic pillar having one or more concave vertical external grooves, the one or more grooves being aligned or linked with the one or more larger faces of the prismatic head; a channel above a base of the prosthesis; and an internal cavity having one or more internal faces, wherein the one or more internal faces are indexed with the one or more larger faces of the prism head, and with the one or more external vertical concave grooves of the prosthetic pillar, wherein the one or more internal faces are configured to index with one or more external faces of a dental implant.

2. The multifunctional prosthetic component of claim 1, wherein the one or more smaller faces are hexagonal in shape.

3. The multifunctional prosthetic component of claim 1, wherein the one or more larger faces are triangular in shape.

4. The multifunctional prosthetic component of claim 1, wherein the one or more smaller faces are hexagonal in shape and the one or more larger faces are triangular in shape.

5. The multifunctional prosthetic component of claim 1, wherein the one or more concave vertical external grooves are aligned with the one or more larger faces of the prismatic head.

6. The multifunctional prosthetic component of claim 1, wherein the one or more concave vertical external grooves are linked with the one or more larger faces of the prismatic head.

7. The multifunctional prosthetic component of claim 1, wherein the internal cavity is hexagonal in shape, and wherein the internal faces of the hexagonal cavity are configured to index the external faces of an external hexagon on a dental implant.

8. A dental implant system, the system comprising: a multifunctional prosthetic component, the multifunctional prosthetic component comprising: a prismatic head having one or more smaller faces and one or more larger faces; one or more grooves below the prismatic head; a prosthetic pillar having one or more concave vertical external grooves, the one or more grooves being aligned or linked with the one or more larger faces of the prismatic head; a channel above a base of the prosthesis; and an internal cavity having one or more internal faces, wherein the one or more internal faces are indexed with the one or more larger faces of the prism head, and with the one or more external vertical concave grooves of the prosthetic pillar, wherein the one or more internal faces are configured to index with one or more external faces of a dental implant; and a cylinder configured to be adapted onto the multifunctional prosthetic component, the cylinder having one or more internal protrusions, one or more external grooves, and one or more convex vertical internal ridges.

9. The dental implant system of claim 8, further comprising: a plastic cover having a channel shaped clamp for accurate fixation of the multifunctional prosthetic component and a cylindrical rod configured to allow fixing of an O-ring of an installation key.

10. The dental implant system of claim 9, further comprising a screw, wherein the screw is configured to fix the multifunctional prosthetic component onto a dental implant, allowing the component's use as a prosthetic pillar.

11. The dental implant system of claim 10, further comprising a dental implant, the implant having one or more external faces.

12. The dental implant system of claim 11, further comprising an installation key, the installation key having an O-ring.

13. The dental implant system of claim 12, wherein the one or more smaller faces are hexagonal in shape, wherein the one or more larger faces are triangular in shape, wherein the internal cavity is hexagonal in shape, and wherein the internal faces of the hexagonal cavity are configured to index the external faces of an external hexagon on a dental implant.

14. The method of use of the dental implant system of claim 12, the method comprising: transporting the plastic cover, the multifunctional prosthetic component and the implant to the bone tissue through the installation key, wherein the O-ring of the key is coupled with the cylindrical rod of the plastic cover fixed to the multifunctional prosthetic component; applying torque on the one or more smaller faces of the prismatic head of the multifunctional prosthetic component; inserting the implant through a connection coupled to a ratchet torque wrench supported on the smaller faces of the prismatic head, allowing for the exact fixing of the assembly; removing the multifunctional prosthetic component of the implant allocated to the bone tissue; using the multifunctional prosthetic component to transfer the molding for making the plaster model; sectioning the multifunctional prosthetic component to separate the prismatic head from the prosthetic pillar; adapting the prosthetic pillar to the cylinder by means of the fitting to the one or more internal projections; constructing the prosthesis temporarily using the prosthetic pillar to form a cylinder/prosthesis group; positioning the prosthetic pillar and cylinder/prosthesis group on the implant in the mouth, wherein the prosthetic pillar is fixed to the implant with a fixing screw; orienting the position of the cylinder/prosthesis group on the prosthetic pillar by the one or more convex internal vertical ridges of the cylinder.

15. The method of claim 14, wherein the molding is transferred with the plastic cover in position.

16. The method of claim 14, wherein the molding is transferred without the plastic cover in position.

Description

DESCRIPTION OF THE DRAWINGS

(1) Exemplary embodiments of the disclosure will now be described by way of example only and with reference to the accompanying drawings, in which:

(2) FIG. 1 shows a perspective view of the components of an example the dental implant system proposed here, which illustrates the cylinder (1), the plastic cover (2), the internal screw (3), the multi-use prosthetic component (4) and the implant (5).

(3) FIG. 2 shows a perspective view of an example of the multi-use prosthetic component, which shows the surfaces (4A and 4B) of the prismatic head (4.1), the guide for the cutting (4C), the section which will become the prosthetic pillar (4.2), the external vertical concave grooves (4D) indexed, or aligned, with the larger surfaces (4A) of the prismatic head (4.1) and the surfaces of the internal hexagon (4F), the channel (4E) for the adaptation of the cylinder (1) with one click, and the internal hexagon (4F).

(4) FIG. 3 shows the cross section of an example of the prismatic head (4.1) of the multi-use prosthetic component (4), where one can see a top view in which there are smaller faces (4B) with a hexagonal shape for the application of torque, and the larger surfaces (4A), triangular shaped for three-dimensional orientation, which may also adopt the hexagonal format.

(5) FIG. 4 shows a perspective view of an example of the indexing, or alignment, between the larger surfaces (4A) of the prismatic head (4.1) the external vertical concave grooves (4D) of the prosthetic pillar (4.2) the inner hexagon surfaces (4F) of the multi-use prosthetic component (4) and the external hexagon faces (5A) of the implant (5) which allows the anti-rotational effect and repositioning accuracy of the multi-use prosthetic component (4) on the implant (5).

(6) FIG. 5 shows a perspective view of an example of the multi-use prosthetic component (4) after its section by a skilled professional using, for example, a common cutting disk as known in the rehabilitation technique, removing the prismatic head (4.1) and therefore obtaining the prosthetic pillar (4.2).

(7) FIG. 6 demonstrates an example of the cylinder (1) on the prosthetic pillar (4.2) and the respective views of slices perpendicular to the longitudinal axes, which show external grooves (1A) for retention of the resin which will be supplied with the prosthesis, the internal protrusions (1B) for engagement with the prosthetic pillar (4.2) with a click, as with the external vertical concave grooves of the pillar that may accept internal convex vertical ridges of the cylinder (1C) for guidance in the positioning of the prosthetic pillar (4.2) and the anti-rotational fitting of the prosthesis.

(8) FIG. 7 illustrates the sequence of a use of an example of this innovation, observing that in step A the capture system, the O-ring (6A) belonging to the key (6) is attached to the cylindrical rod (2A) of the plastic cover (2) which is attached to the multi-use prosthetic component (4) by means of the clamp-shaped channel (2B) while the multi-use prosthetic component (4) is attached to the implant (5) by the attachment screw (3).

(9) In step B the uncoupling of the plastic cover can be seen (2) after the molding transfer process, which prevents the entry of molding material into the hole to insert the attachment screw (3).

(10) Step C illustrates the section of the multi-use prosthetic component (4) done by a cutting disc, that results in two parts: the prismatic head (4.1) and the prosthetic pillar (4.2) which, after cutting, is again attached to the implant (5) by the attachment screw (3).

(11) In step D the cylinder is checked (1) before placing it on the prosthetic pillar (4.2). Step E illustrates the cylinder (1) already attached to the prosthetic pillar (4.2).

DETAILED DESCRIPTION

(12) In one aspect, the proposed innovation is a multifunctional prosthetic component. In one example, the multifunctional prosthetic component (4), is endowed with internal hexagon (4F), a set screw system (3) and a cylinder for making a dental prosthesis (1). Specifically, examples of the multi-use prosthetic component (4) provide the innovation in its use in several distinct functions: a) capturing the packaging, transportation, installation and application of torque; b) impression coping; c) prosthetic post indexed to the implant; and d) 3D orientation of the device during the surgical procedure.

(13) In the traditional technique, the implant (5) may be introduced by means of a conventional assembler that is used only for transport to the bone tissue and the application of torque, and is then immediately discarded because it has no further use, therefor providing the adaptation of a conventional prosthetic component.

(14) With the use of certain examples it is proposed that the multi-use prosthetic component (4) has a plastic cover (2) in its upper portion, which has a channel shaped clamp (2B) for the accurate mounting on the multi-use prosthetic component (4) and a cylindrical rod (2A) to allow the fixing on the O-ring (6A) of the installation key (6).

(15) With the aid of the installation key (6), the whole assembly, consisting of the plastic cover (2), the screw (3), the multi-use prosthetic component (4) and the implant (5) is captured at the region of the cylindrical stem (2A) of the plastic cover, allowing its transport to the bone tissue (FIG. 7, A).

(16) In certain examples, the multi-use prosthetic component (4) presents in its physical configuration a prismatic head (4.1) containing smaller surfaces (4B) with a hexagonal shape, used for the application of torque, as well as larger surfaces (4A), with triangular profile in its cross section, that are used for the 3D orientation, which may also adopt a hexagonal form. Optionally, the faces may have different and compatible shapes, for example, larger faces (4A) associated with a hexagonal prismatic head (4.1) with 12 sides.

(17) In certain examples. these surfaces (4A and 4B) of the prismatic head (4.1) are indexed, i.e. aligned, with the inner hexagon surfaces (4F) multi-use prosthetic component (4) that, consequently, are indexed with the surfaces of the external hexagon (5A) of the implant (5). This allows the exact positioning of a prosthetic unit, because it limits the rotation of the multi-use prosthetic component to six (6) precise positions, creating an anti-rotational effect (FIG. 4). In the case described above, for example, there are six possible positions for the allocation of the prosthetic component.

(18) The orientation function of the assembly at the time of installation of the implant (5) is ensured by means of external vertical concave grooves (4D) arranged along the body of the prosthetic pillar (4.2), which are indexed with the larger surfaces (4a) of the prismatic head (4.1). Thus, at least one slot is marked on the body of the prosthetic pillar (4.2) to enable indexing with the larger faces (4A) of the head prism (4.1).

(19) The multi-use prosthetic component (4) has a groove (4C) below the prismatic head (4.1), which guides the skilled professional to perform the cutting, with a common use disc that is known in the rehab area (FIG. 5) that will transform the multi-use prosthetic component (4) in a prosthetic pillar (4.2).

(20) The presence of an attachment screw (3) determines the attachment of the multi-use prosthetic component (4) on the implant (5), enabling it to be used as a prosthetic pillar (4.2). As a prosthetic pillar (4.2), the multi-use prosthetic component may be used as 3D orientation device for installing more than one implant during the same surgical procedure.

(21) However, the multi-use prosthetic component (4) has a circular channel (4D) above the prosthetic base plate, where the cylinder (1) is fitted with only one click, ensuring safety when adapting the crown.

(22) The cylinder (1), in turn, has an internal projection (1B) for the exact fitting of the prosthetic pillar (4.2) with a click, besides the external grooves (1A) for the retention of the resin that will be supplied with the prosthesis. There are also internal convex vertical ridges (1C) for guidance when locating the prosthetic pillar (4.2).

(23) The multi-use prosthetic component (4) allows one to carry out the impression transferring the implant (5), making the technique easier due to the surfaces on the (4A and 4B) prismatic head (4.1), minimizing the risk of errors in the orientation of the final prosthesis.

(24) Moreover, the presence of the plastic cover (2) provides protection of the internal portion of the multi-use prosthetic component (4) during the transfer process of the molding because it prevents the entry of molding material, facilitating the access of the fixing screw (3).

(25) In summary, examples of the component (4) enable the optimization of the technical installation of dental implants, adopting the multifunctional prosthetic component (4) the association of the function of a conventional assembler with at least one of the additional functions of capture, transport, installation, application of torque; transfer molding; indexed abutment to the implant, as well as three-dimensional orientation device.

(26) This configuration of the multifunctional prosthetic component (4) establishes a method for the specific use, able to enjoy the features offered by the artifact. Thus, in an example scenario of everyday use for the use of implant (5), an installation key may be used (6) to remove the component (4) from packaging, where the O-ring (6A) of the key (6) is coupled in the cylindrical rod (2A) of the plastic cover (2) which is fixed to the multifunctional prosthetic component (4) by means of the clamp-shaped channel (2B) while the multifunctional prosthetic component (4) is attached to the implant by the fixing screw (3). This entire cover assembly (2), multi-functional prosthetic component (4) and the implant (5) is removed from the package and taken to the bone tissue with the key (6), which initiates the torque application on the smaller faces (4B) of prismatic head (4.1) of the multifunctional prosthetic component (4). The completion of the insertion of the implant (5) continues by way of a connection coupled to a ratchet torque wrench, also supported on the smaller faces (4B) of the prismatic head (4.1), allowing for the exact fixing of the assembly.

(27) After completion of the installation of the implant (5), the dentist will perform the process of transfer molding, still with the plastic cover (2) in position, preventing the entry of molding material in the internal portion of the multifunctional prosthetic component (4), and the screw hole (3).

(28) After this process, the practitioner removes the multifunctional prosthetic component (4) by unscrewing it from the implant (5) that is already in the bone tissue, and uses it as transfer molding for making the plaster model.

(29) In this step, the practitioner removes the multifunctional prosthetic component (4) of the model and performs its section through a commonly used disc laboratory technique, obtaining the prismatic head (4.1), which is discarded, and the prosthetic pillar (4.2), which returns the model for the adaptation of the cylinder, which is fitting conducted through a click on their internal projections.

(30) Once adapted on the cylinder, which has external grooves for retaining the resin, the prosthesis is constructed by means of currently known techniques.

(31) At the end, the prosthetic pillar (4.2) and the cylinder/prosthesis assembly are removed from the model and positioned over the implant (5) in the mouth, where the prosthetic pillar (4.2) is fixed to the implant (5) with a fixing screw (3), and the cylinder/prosthesis assembly is again embedded in the prosthetic pillar (4.2) with one click, associated with or without the cementing process. The orientation of the positioning cylinder/and the temporary prosthesis in the pillar (4.2) and anti-rotational fitting of the prosthesis are guaranteed by the vertical internal convex ridges of the cylinder.

(32) This innovation is not limited to the aspects, examples and representations discussed or shown herein, and must be understood in its widest scope. Many modifications and other representations will come to the mind to those skilled in the area to which this innovation belongs, having the benefit of the teachings presented in the foregoing descriptions and annexed drawings. Furthermore, it is to be understood that the innovation is not limited to the specific forms disclosed, and that modifications and other forms are understood as being included within the scope of the annexed claims. Although specific terms are employed herein, these are used only in a generic and descriptive form and with a limiting purpose.