A bite registration device including a scan post configured to attach to a dental implant, a bite pillar configured to be attached at a coronal end of the scan post, and a mechanism for attaching the bite pillar to the scan post, wherein the mechanism enables adjustment of a distance from a coronal end of the bite pillar to an apical end of the scan post. A bite pillar including a wide coronal end and an elongate shape configured to attach to an object in a mouth of a patient. A scan post including a screw thread for attaching a bite pillar thereto. A reference pillar configured as an elongate shape to be attached at a first end to an object in a mouth of a patient. Related apparatus and methods are also described.

An oral hygiene device is provided. The oral hygiene device includes a body having a base and first and second opposing sides extending from the base and defining a gap there between. The device may further include a plurality of corresponding notch pairs, wherein each corresponding notch pair has a first notch positioned in the first opposing side and a second notch positioned in the second opposing side. The location of the notch pairs may coincide with a user's mouth and in particular to the position of the user's teeth within the mouth. As such, a fibrous material, such as floss, may be coupled to the device such that the material spans the gap between at least one of the corresponding notch pairs so that the material may be inserted into the spaces between the user's teeth when the device is placed into the user's mouth.

A secure computation device obtains concealed information {M(i.sub.0, . . . , i.sub.S−1)} of a table M(i.sub.0, . . . , i.sub.S−1) having one-variable function values as its members. It is to be noted that M(i.sub.b, 0, . . . , i.sub.b, S−1) generated by substituting counter values i.sub.b, 0, . . . , i.sub.b, S−1 into the table M(i.sub.0, . . . , i.sub.S−1) represents a matrix M.sub.b, γ, μ, which is any one of M.sub.b, 2, 1, . . . , M.sub.b, 3, 2. The secure computation device obtains concealed information {M.sub.b, γ, μ} by secure computation using concealed information {i.sub.b, 0}, . . . , {i.sub.b, S−1} and the concealed information {M(i.sub.0, . . . , i.sub.S−1)}, and obtains concealed information {M.sub.b, Γ, MU} of a matrix M.sub.b, Γ, MU, which is obtained by execution of a remaining process including those processes among a process P.sub.j, 1, a process P.sub.j, 2, a process P.sub.j, 3, and a process P.sub.j, 4, that are performed subsequent to a process P.sub.γ, μ.

A method of producing a custom dental anchor application appliance may be provided. The appliance may be for mounting one or more anchors to teeth of a patient. The appliance may be for use in orthodontic aligner treatment. The method may include forming a dental appliance. The forming may be done using a three-dimensional printing approach. The appliance may include a body. The body may include at least one anchor-locating area. The anchor-locating area may be shaped to conform to a mounting area on a surface of a tooth. The appliance may include a receiving structure. The receiving structure may be configured to removably support a dental anchor. The dental anchor may be of a predefined configuration in a fixed position and orientation relative to the body.

A method is used to provide a dental prosthetic with an upper boundary that cannot be seen when a patient smiles with the dental prosthetic installed. The method includes tracing a smile line on a dental appliance while the dental appliance is in the patient's mouth and while the patient is smiling. The method then includes transferring that smile line from the dental appliance to a study cast of the patient's mouth. The study cast is then scanned to create a three-dimensional digital model that includes the transferred smile line. The three-dimensional digital model is used to generate a surgical plan and surgical hardware for installation of the dental prosthetic. The dental prosthetic may include a full arch restoration.

The present disclosure provides methods, computing device readable medium, devices, and systems that utilize a cheek retractor and/or a mobile device holder for case assessment and/or dental treatments. One cheek retractor includes a first and a second lip holder, both including imaging markers of a predetermined size to determine a scale of teeth of a user, where each imaging marker is located a predefined distance from the remaining imaging markers, and where the lip holder is to hold a cheek away from a mouth of a user to expose teeth of the user. A mobile device holder can include elements to receive a mobile device to capture images of the patient's teeth.

Radically polymerizable dental material, which contains at least one ABA or AB block copolymer, preferably at least one monofunctional, radically polymerizable monomer (a) and preferably at least one radically polymerizable urethane di(meth)acrylate telechel (b).

Example embodiments of the present invention provide a multi-function oral appliance, comprising an elastomeric polymer, a hard non-elastic polymer, or a combination of the two fused together; formed using 3D printing or vacuum-forming; configured to engage all or part of the bottom and top teeth such that the lower jaw is advanced, e.g., 8 mm, anterior to its habitual resting position and opened, e.g., 8 mm, from its habitual resting position when the appliance is applied; and configured such that, e.g., 90%, or more, of airflow through the mouth is blocked by the appliance. In some embodiments, the appliance is configured to include gel-wells in the interior of the appliance.

Method and apparatus embodiments can generate a volume fluorescence image of a tooth. Method and apparatus embodiments can project structured light patterns onto a tooth and generate a contour (volume) image of the tooth surface from acquired corresponding structured light projection images; then acquire one or more fluorescence images of the tooth generated under blue-UV illumination. A composite image that shows fluorescence image content mapped to the generated contour image can be transmitted, stored, modified and/or displayed.

A virtual model of an intraoral cavity is provided, wherein this process is initialized by a dental clinic, and the design and manufacture of a suitable dental prosthesis for the intraoral cavity is shared between a dental lab and a service center.