A method for monitoring the positioning of the teeth including production of a three-dimensional digital initial reference model of the arches of the patient and, for each tooth, definition, from the initial reference model, of a three-dimensional digital reference tooth model; acquisition of updated image of at least one two-dimensional image of the arches in actual acquisition conditions; analysis of each updated image and production, for each updated image, of an updated map; optionally, determination, for each updated image, of rough virtual acquisition conditions approximating the actual acquisition conditions; searching, for each updated image, for a final reference model corresponding to the positioning of the teeth during the acquisition of the updated image, for each tooth model, comparison of the positionings of the tooth model in the initial reference model and in the reference model obtained at the end of the preceding steps to determine the movement of the teeth

A computer system and computerized method in which orthodontic treatment, including midcourse correction of one or more teeth in a dental arch fitted with a dental appliance, comprises a virtual simulation of a dental arch fitted with a virtual dental appliance in which each of the one or more teeth can be discretely moved from an initial position to a final position allowing modification of the fitted dental appliance by computerized selection of one or more brackets and production of a bonding tray adapted to hold the selected brackets in correspondence to determined bracket bonding locations in the virtual simulation of dental arch.

A device including one or more preformed or customized eruption guidance appliances placed in an individual's mouth. The preformed appliances are vibrated with a pulsation device to encourage tooth eruption by increasing the force and efficiency of the eruption toward a preferred location and a preferred alignment as well as providing increased blood flow and blood oxygen flow to the muscles and tissues in and around the oral cavity of the individual. The preformed guidance appliance driven by the pulsation device is selected from a range of guidance appliances, each of which is selected by size and shape to fit an individual based on the individuals anticipated tooth and jaw size as well as the growth profile. The pulsation can increase the blood and oxygen flow to the many muscles that surround the appliances outside surfaces that can alter mouth breathing, prevent impingement of the oropharynx from the abnormal distalization of the tongue and mandible during sleep, the proper resting posture of the tongue, increased nasal breathing, prevent snoring, improve abnormal swallowing, correct thumb sucking and various abnormalities of speech.

Systems and techniques are described for determining at least one of a translational force or a rotational force applied by a dental appliance to a tooth or teeth of a patient. A system includes model teeth configured to represent a portion of a dental arch and receive a dental appliance, a post extending from a first end coupled to a respective tooth to a second end coupled to a base, at least one strain gauge integrally formed on a surface of the post between the first end and the second end, and processor communicatively coupled to the at least one strain gauge and configured to determine at least one of a translational force or a rotational force applied by the dental appliance to the respective tooth.

Systems and methods are disclosed for user modification of a rule or set of textual rules in plain language the reference instructions in a domain-specific treatment language that is used to generate dental appliance data. In some cases, the user may interact with a graphical user interface to modify a practitioner-specific subset of textural rules. The graphical user interface may allow modification of the practitioner-specific subset of textural rules without prior knowledge of the domain-specific treatment programming language. Each interaction region may cause sections of the predefined treatment preferences to be modified without knowledge of the dental protocol language. The example systems, methods, and/or computer-readable media described herein help with designing treatment plans for orthodontic treatments, including treatment plans based on predefined treatment preferences expressed in a dental protocol language.

Systems for treatment planning environments are disclosed where a method of collaborating on a treatment plan for correcting one or more teeth of a subject may include digitally receiving intra-oral scan data of one or more teeth of the subject where the one or more teeth are in an initial position, synchronizing a virtual treatment planning environment between a first device of at least one practitioner and a second device of at least one technician, and displaying a pre-setup design of the intra-oral scan data within the treatment planning environment. The pre-setup design is revised based upon input received from the practitioner for correcting one or more malocclusions and one or more intermediate steps of the treatment plan is created from the initial position to a final position of the teeth within the treatment planning environment. The treatment plan may be finalized by the practitioner within the treatment planning environment

A method and a system for determining occlusal contacts between lower teeth and upper teeth of a subject are provided. The method comprises: receiving a 3D model including a first portion and a second portion including points respectively representative of the lower teeth and the upper teeth; determining an occlusal plane associated with the second portion of the 3D model; determining, from each point of the first portion, respective distance values to the occlusal plane; and identifying, within the points of the first portion, based on the respective distance values, using a voxel grid, a set of occlusal points representative of at least some of the occlusal contacts between the lower teeth and the upper teeth.

System and methods for positioning 3D virtual brackets on teeth for the precise positioning of conventional brackets and wire. Various reference features may be calculated for the teeth and used to calculate a position for the virtual bracket. Reference features that are calculated include curve of Spee, Andrew's plane, and a facial axis of the clinical crown for the teeth.

Provided herein are curable compositions for use in a high temperature lithography-based photopolymerization process, and telechelic block polymers and methods of using such polymers in curable compositions to produce medical devices such as orthodontic appliances comprising the polymeric compositions comprising the telechelic block polymers.

A system includes a plurality of tooth models each including computer code controlling its movement. The system also includes a tooth movement control system (TMCS) with a processor executing a dental manager module and with memory scoring a different tooth movement plan for each of the tooth models. In practice, the tooth movement plans are stored in the memory of each of the tooth models (e.g., a different tooth movement plan for each tooth model). Then, during tooth movement operation, each of the local control modules independently controls the tooth model to execute the tooth movement plan stored in the memory of the tooth model.