A dental device having one or more scan bodies and a frame member is described. Each scan body has a longitudinal axis and a wing region that extends radially outwardly from the longitudinal axis. The scan bodies are attached to dental fasteners in a dental arch and the frame member is attached to the wing regions of the scan bodies to form a physical verification jig. The scan bodies are scanned using an intraoral scanner either before or after attaching the frame member. The scan bodies have a three-dimensional digital image file. CAD software aligns the scanned images to the image files and stiches multiple captures of the dental arch together. A dental device having at least two scan bodies and no frame member is also described. The scan bodies are attached to dental fasteners in a dental arch and the wing regions are positioned so as to converge.

Methods of forming interproximal reduction guides are described herein. These interproximal reduction guides apparatuses may include a body that fits over the patient's dental arch and one or more guide slots formed in them configured to limit the motion of an interproximal reduction cutting tool in a defined manner.

A temporary alignment system and method for holding a dental coping to an implant abutment using the same threads in the abutment that are used for definitive attachment are disclosed. The disclosed temporary fasteners initially orient and hold a coping against an abutment with a force along the same axis as the semi-definitive screw. The aligned coping can be picked-up in a closed-tray impression process without unscrewing the temporary fastener. Embodiments include threaded posts that release copings from the abutment through axial forces. Some embodiments include a threaded post with separable cap that is picked-up with the coping. Methods for converting an existing prosthesis for screw attachment to implants in a single visit and digital capture of the converted prosthesis are described.

A dental method and associated apparatus is disclosed in which a navigation body, comprising a plurality of navigation elements, is scanned using a scanner. Relative locations of the navigation elements are determined and, based on the relative locations, a scanner coordinate system is determined. A dental model is also scanned using the scanner to obtain three-dimensional virtual image data of the dental model and the scanner coordinate system is associated with the image data. A three-dimensional virtual image of the dental model is positioned, based on the three-dimensional virtual image data, within a three-dimensional virtual scene. The virtual scene is associated with a virtual articulator coordinate system, and the positioning of the virtual image within the virtual scene comprises positioning and orienting the virtual image relative to the virtual articulator coordinate system based on a transformation of the virtual image data from the scanner coordinate system to the virtual articulator coordinate system.

Example fiducial markers include features that make them particularly useful in dental scanning methods for analyzing jaws of a patient, wherein the dental scanning methods involve taking multiple scans of the jaws, and/or models thereof, and then shifting the image of one scan to match that of another. Prior to scanning, the fiducial markers are attached to the patient's jaws to accurately identify and track the relative position of the jaws.

An extraoral dental scanner for three-dimensional capture of the surface of a dental shaped part (300) with a 3D measuring camera (102) having an optical axis (106), wherein the means for the machine-controlled relative positioning of the 3D measuring camera (102) and the dental shaped part (300) are embodied in such a way that the means for taking up and positioning the dental shaped part (300) can be moved into a parking position outside a region that can be captured optically by the 3D measuring camera (102), with a work plate (708) for manually positioning the dental shaped part (300) in the measurement volume (144) of the 3D measuring camera (102), wherein the work plate (708) is aligned perpendicularly to the optical axis (106) and wherein the work plate (708), as viewed from the 3D measuring camera (102), is arranged behind the means for taking up and positioning the dental shaped part (300), makes it possible to record uninterrupted 3D image data with very short recording times both by automatic and by manual positioning of dental shaped parts of different sizes and embodiment variants.

Disclosed are example embodiments of methods and systems for identifying and quantifying manufacturing defects of a manufactured dental prosthesis. Certain embodiments of the system for performing quality control on manufactured dental prostheses includes: a quality control module configured to determine whether the dental prosthesis is a good or a defective product based at least on a differences model generated by comparing a design model and a scanned model of the manufactured dental prosthesis.

Interproximal reduction guides apparatuses and methods of making and using them are described herein. These interproximal reduction guides apparatuses may include a body that fits over the patient's dental arch and one or more guide slots formed in them configured to limit the motion of an interproximal reduction cutting tool in a defined manner.

Interproximal reduction guides apparatuses and methods of making and using them are described herein. These interproximal reduction guides apparatuses may include a body that fits over the patient's dental arch and one or more guide slots formed in them configured to limit the motion of an interproximal reduction cutting tool in a defined manner.

A system for scanning a dental arch of a patient includes a reference element having a reference pattern thereon; a holding mechanism configured to hold the reference element in a fixed position inside the patient's oral cavity adjacent to and spaced from the dental arch, wherein the holding mechanism is configured to be installed on the patient without contacting an occlusal surface of the dental arch; and an intra-oral scanner configured to scan the dental arch and an adjacent portion of the reference element to obtain a scanned image comprising the scanned portion of the dental arch and the scanned adjacent portion of the reference pattern.