Packaging systems for dental implants and methods for implanting a packaged implant are provided herein. The packaging system includes a housing and a cap forming an enclosure for a dental implant and corresponding healing screw. The housing includes a first and second base portion that interact with a platform that receives a portion of the dental implant to present the dental implant to a user during use.

An intra-procedure dental implant stabilization and healing system that includes a soft tissue forming scanning abutment and associated, temporary crown. After initial implant placement, a scanning abutment of the present system is attached to the implant and serves, both as a scanning body and, in combination with a temporary crown attached thereto, as a healing cap. Use of the system obviates an additional surgical incision to reach recipient osseointegrated implant, as is required in conventional implant procedures, as well as the need for a conventional impression coping, separate healing cap, temporary abutment and temporary crown.

A socket grafting plugs system for use in a socket grafting process. Each socket grafting plug has a first cross section, a second cross section parallel to the first cross section and a body portion extending between the first cross section and the second cross section. The first cross section belongs to a group of first plug sections with at least a combination of three different shapes with three different sizes.

Methods for manufacturing anatomical healing caps, including forming an anatomical healing cuff body for a given tooth position, the anatomical healing cuff body having a cross-section and an exterior surface so that the anatomical healing cuff body provides substantially custom filling of at least an emergence portion of a void where a natural tooth once emerged from the void or where a tooth would have emerged from a void of the given tooth position, and forming both lateral buccal and lingual handle extensions extending from the anatomical healing cuff body so that the manufactured anatomical healing cap includes a laterally extending buccal handle extension and an oppositely disposed laterally extending lingual handle extension, the buccal and lingual handle extensions being integrally formed with the healing cuff body. The healing caps can be formed using a casting jig, by machining, by 3D printing, or other suitable methods.

A system for dental implant restoration is provided. It includes universal aligning adaptors and prosthetic components having co-operable indices, which together form a translational, integrating system which aligns, synchronizes, and references the prosthetic components about an implant's central axis of rotation. Rotation of an adaptor about a prosthetic component, with its reference point becoming aligned to a predetermined reference point on the prosthetic component, followed by the rotation of the adaptor/prosthetic component assembly about the implant, situates the prosthetic component in a predetermined position such that all other prosthetic components become synchronized to the adaptor's reference point. The prosthetic component is mechanical for clinical or lab bench use, or is virtual for restoration design in a software program, prior to milling prosthetic abutments or devices. Abutments, healing caps and screw access holes are realigned to preferred positions and synchronized with minimal deviation from the ideal direction.

Methods and dental prosthetics for providing soft tissue adhesion to a temporary healing abutment, or other dental prosthetic (e.g., temporary or permanent). Existing prosthetics generally do not provide any significant adhesion of the soft tissue surrounding the prosthetic, to the outer surface of the prosthetic itself. Because of the presence of gaps between such structures, or simple non-adhesion even where the structures may touch (but be free and unattached relative to one another), there is a tendency for pathogenic microbes to enter into such space between the structures, and for the soft gingival tissue to recede, particularly in patients with thin type periodontal tissue. The present disclosure provides materials and/or surface treatment (e.g., texturing) that ensures good bonding between the prosthetic and the soft tissue, reducing risk of infection, and reducing undesirable gingival recession surrounding the prosthetic anchored on a dental implant.

The present invention relates to endosseous implants and in particular, to screw form dental implants for implanting within bone. The bone implant is configured to be a self-drilling bone implant that is adept at condensing, collecting and distributing bone along all of the implant's surface and within the implantation site, to significantly increase the bone implant contact surface. The implant is configured to have a coronal portion and a body portion that are continuous with one another. The coronal portion is configured to have a smaller overall diameter than the overall diameter of said body portion. The body portion is fit with threading that facilitates the self-drilling and bone collection properties when the implant is rotates in both the clockwise and counterclockwise directions.

A method of taking a scan of a patient's oral cavity may include providing an anatomical healing cap that can be received within a subgingival void of a given tooth position. The method may also include taking a first scan (e.g., an extraoral scan) of the anatomical healing cap before seating the anatomical healing cap into the subgingival void of the given tooth position, where the anatomical healing cap is coupled to an implant disposed adjacent the anatomical healing cap. Further, the method can involve taking a second scan (e.g., an intraoral scan) of the anatomical healing cap and surrounding surfaces, and then integrating the two scans into an overall oral cavity scan. Reference points from the first scan may be used to align the second scan with the first scan, integrating the two together.

The present invention addresses above-noted objectives by providing a dental component that includes a coronal end, an apical end, and a longitudinal axis extending between the coronal end and the apical end. The dental component also includes an interface for assembly to another dental component, the interface comprising at least one indexing section for rotationally locking the dental component to the other dental component and at least one guiding section. The at least one guiding section and the at least one indexing section alternate about the longitudinal axis, wherein the guiding section includes an apically facing or coronally facing guiding surface. Further, a tangent to at least a portion of the guiding surface has a slope towards the next indexing section about the longitudinal axis.

A dental implant assembly comprising a healing component (10) removably attachable to a coronal end of a dental implant (40) and an impression component (20) having an outer surface, an upper portion (21) and a lower portion (22) and being removably attachable to the healing component (10). The healing component (10) has an internal bore (13) for receiving at least part of the lower portion (22) of said impression component (20) therein and the internal bore having a shoulder on an inner surface thereof acting as an axial locator providing an endstop for axial movement of said impression component (20) within said bore (13). The assembly further comprises a rotational locator limiting rotational movement between said impression component (20) and said healing component (10), the rotational locator comprising a formation on said outer surface of the impression component (20) and/or a formation on said inner surface of said bore (13) of the healing component (10). Using this assembly, a digital impression recording positional information about the dental implant can be taken without having to remove the healing component (10) from the implant (40).