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.

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.

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.

The invention relates to a method for producing a guided bite splint for a supporting jaw comprising at least one guide for an opposing jaw. A 3D model of an upper jaw and/or a 3D model of a lower jaw are available, wherein the 3D models of the upper jaw and the lower jaw are arranged relative to one another in an occlusal position and integrated into a virtual articulator model which simulates an articulation movement of the lower jaw relative to the upper jaw, wherein a 3D model of the bite splint is constructed using the 3D model of the upper jaw and/or the 3D model of the lower jaw, wherein the at least one guide for the opposing jaw is constructed automatically on the 3D model of the bite splint with the aid of a computer.

The invention relates to a method for producing a guided bite splint for a supporting jaw comprising at least one guide for an opposing jaw. A 3D model of an upper jaw and/or a 3D model of a lower jaw are available, wherein the 3D models of the upper jaw and the lower jaw are arranged relative to one another in an occlusal position and integrated into a virtual articulator model which simulates an articulation movement of the lower jaw relative to the upper jaw, wherein a 3D model of the bite splint is constructed using the 3D model of the upper jaw and/or the 3D model of the lower jaw, wherein the at least one guide for the opposing jaw is constructed automatically on the 3D model of the bite splint with the aid of a computer.

The invention relates to a device for measuring dental parameters, more specifically for measuring alignment, bite pressure and dental occlusion in a subject, the device being formed from a main body containing a light source and at least one image-recording element linked with an image processor disposed in a control unit. The device includes a cartridge that is inserted automatically into the main body, the cartridge including a support for a plate of soft material for imprinting the bite of a subject. The main body also contains traction elements for the plate support and, optionally, for the at least one image-recording element, as well as a display screen disposed on the outside of said main body.

The invention relates to a device for measuring dental parameters, more specifically for measuring alignment, bite pressure and dental occlusion in a subject, the device being formed from a main body containing a light source and at least one image-recording element linked with an image processor disposed in a control unit. The device includes a cartridge that is inserted automatically into the main body, the cartridge including a support for a plate of soft material for imprinting the bite of a subject. The main body also contains traction elements for the plate support and, optionally, for the at least one image-recording element, as well as a display screen disposed on the outside of said main body.

Methods and systems for establishing dental occlusion are described herein. These systems and methods can be used for 1-, 2-, or 3-piece maxillary orthognathic surgeries. An example computer-implemented method includes receiving a maxillary dental model and a mandibular dental model, identifying a plurality of dental landmarks in each of the maxillary and mandibular dental models, and extracting a plurality of points-of-interest from each of the maxillary and mandibular dental models. The dental landmarks include a plurality of maxillary dental landmarks and a plurality of mandibular dental landmarks. The method further includes aligning the maxillary and mandibular points-of-interest, and fine tuning the alignment of the maxillary and mandibular dental models to achieve maximum contact with a collision constraint.

Methods and systems for establishing dental occlusion are described herein. These systems and methods can be used for 1-, 2-, or 3-piece maxillary orthognathic surgeries. An example computer-implemented method includes receiving a maxillary dental model and a mandibular dental model, identifying a plurality of dental landmarks in each of the maxillary and mandibular dental models, and extracting a plurality of points-of-interest from each of the maxillary and mandibular dental models. The dental landmarks include a plurality of maxillary dental landmarks and a plurality of mandibular dental landmarks. The method further includes aligning the maxillary and mandibular points-of-interest, and fine tuning the alignment of the maxillary and mandibular dental models to achieve maximum contact with a collision constraint.

The present invention is a device for simulating lower jaw activity. The device can be utilized in cooperation with an artificial intelligent lower jaw occlusion and attitude recording device. The device comprises a base, an upper jaw tooth mold, an opening and closing rotating platform, a left and right rotating platform, a horizontal rotating platform, a front-back shifting platform and a lower jaw tooth mold. The present invention makes it possible to make lower jaw moving forward and backward, opening and closing (pitch), tilting left and right (yaw), in place rotating (yaw), and etc. Then, according to the data obtained by the artificial intelligent lower jaw occlusion and attitude recording device, the lower jaw activities concluded through the reverse engineering by means of the present invention facilitates production of accurate intra-oral device, and can be applied to unknown complex actions in dental medical research, such as occlusion, bruxism, swallowing, sounding, and etc.