A computer-implemented method/system of determining a trim-line includes receiving a 3D digital dental model; combining the one or more virtual teeth; determining a distance field; determining a first iso-line; determining a back distance field; determining a second iso-line to generate a trim-line. A computer-implemented method/system of segmenting the 3D digital dental model includes receiving a 3D digital dental model; determining an initial virtual tooth location of one or more virtual teeth; constructing a virtual crown line; determining a long axis of one or more virtual teeth; constructing a virtual root line; determining a virtual tooth virtual bounding box; performing an initial segmentation; performing final segmentation.

Disclosed is a method for manufacturing an orthodontic appliance, including the following steps: producing a scanned image of a row of teeth in an initial position; then in a position sought; then producing of a scanned image of the orthodontic appliance, the appliance including an orthodontic arch and at least one fastening element for attachment to a tooth. The orthodontic device is configured for being assembled to the row of teeth in the initial position, so that the arch will take a planar shape when the row has moved into the position sought. The method further includes the following steps: producing a scanned image of the orthodontic arch in the planar shape; then manufacturing the arch from the image by cutting a plate of solid shape memory material.

Techniques for preparing a model (e.g., a digital model) of a person's teeth are described. The techniques include receiving a model of a maxillary arch and a mandibular arch of a person's teeth, operating an automated mesh cleaning operation to modify the model, segmenting the model to identify individual teeth and gum tissue in the model, identifying and marking features of each tooth of the model, and adjusting the individual teeth of the model into a recommended orientation relative to each other, and applying a treatment method. The treatment method may include a selection of a bracket type and an aligner type. The techniques may determine a proposed location of brackets or aligners on the individual teeth based on the applied treatment method and export a digital model of a bracket tray for formation of a bracket tray that can be used to secure the brackets to a person's teeth.

The invention relates to a material for use as construction material for energy-pulse-induced transfer printing, which contains (a) at least one polymerizable binder, (b) at least one volume expansion component, (c) at least one initiator for the polymerization and (d) preferably at least one energy transformation component. The invention furthermore relates to a process for producing three-dimensional objects using the material.

The present invention relates generally to systems, devices, and methods for tracking compliance of orthodontic appliance usage, and more specifically to systems, devices, and methods for tracking compliance of orthodontic appliance usage using a compliance device and/or a light therapy apparatus. The invention provides compliances device that can be configured to be disposed within a patient's mouth. In some embodiments, the compliance device can comprise a sensor configured to detect an input associated with whether an orthodontic appliance is at least partially disposed within the patient's mouth at a first time and at a second time, with the second time being subsequent to the first time.

A method for training a neural network intended to analyze a dental situation of an updated patient. A historical learning database is created that relates to a dental body and to a spatial attribute associated with the dental body. The historical learning database includes more than 1,000 historical records, with each historical record relating to a respective historical patient. Each record including a set of historical images all depicting the dental body in the historical patient, called “historical dental body” and an item of spatial information including, for the historical patient, a set of values for the spatial attribute, called “historical spatial information.” The neural network is trained, by providing it with the sets of historical images as input and with the historical spatial information as output, with the spatial attribute defining an ordered sequence of variables in a three-dimensional reference frame.

Polymeric shell appliances are provided in which the polymeric shell appliances are configured to provide one or more activation forces to facilitate tooth movement. In many embodiments, the activation forces are arranged to provide force in a direction opposite to an intended direction of tooth movement. The polymeric shell appliances may comprise one or more tooth receiving cavities, in which each of the plurality of tooth receiving cavities is shaped and arranged to provide a counter moment of each of the plurality of teeth.

An orthodontic force measurement system that enables duplication of the patient’s dentition for the application of appliances in a simulated clinical condition. Six components of the load system on individual teeth can be measured. The device can take patient-specific information, such as shapes and locations of the teeth, and duplicate them on the device. Clinicians will be able to apply different appliances to the denture and measure the load system on specific teeth. By accurately quantifying force/moments on individual teeth, individualized, predictable patient-specific orthodontic treatments can be implemented.

An orthodontic force measurement system that enables duplication of the patient’s dentition for the application of appliances in a simulated clinical condition. Six components of the load system on individual teeth can be measured. The device can take patient-specific information, such as shapes and locations of the teeth, and duplicate them on the device. Clinicians will be able to apply different appliances to the denture and measure the load system on specific teeth. By accurately quantifying force/moments on individual teeth, individualized, predictable patient-specific orthodontic treatments can be implemented.

The method for generating dental data suitable for manufacturing of a dental aligner, includes storing 3D scan data of a dental arch, determining (140) a curve in an occlusal plane, determining a positioning of the nodes of the teeth of the dental arch on the curve, determining an elevation of the nodes of the teeth of the dental arch, and determining an orientation of the teeth of the dental arch; said manufacturing data are calculated at least on the basis of the 3D scan data as well as the determined positioning, the determined elevation, and the determined orientation.