A training method for evaluating the bonding accuracy of orthodontic brackets is provided. The evaluation method includes a training device for racket bonding accuracy evaluation which includes virtual teeth with root-shaped connectors and an evaluation base to fix the virtual teeth. Multiple reference lines are marked on the evaluation base, and their intersection is set as the evaluation point. When the virtual tooth is fixed to the evaluation base, the reference lines and the evaluation points are utilized for rapid evaluation of the bonding accuracy of the bracket. Moreover, thanks to their horizontal arrangement, when there are multiple virtual teeth, the evaluation of bracket bonding would be more intuitive and efficient than using the traditional articulator.

A magnetic orthodontic device has two correction appliances. Each of the correction appliances has a linkage portion, a first connecting portion, a second connecting portion, an adhering plate, a neodymium magnet, and a shell. The linkage portion is elongated and has two opposite ends. The first and second connecting portions are respectively disposed at the two opposite ends of the linkage portion. The adhering plate is disposed at the first connecting portion. The neodymium magnet is disposed at the second connecting portion. The adhering plate and the neodymium magnet respectively protrude toward opposite directions. The shell surrounds the neodymium magnet. The neodymium magnets of the two correction appliances are capable of repelling or attracting each other.

Disclosed is an orthodontic composite, comprising: an orthodontic member which has a tube shape, a hollow polygonal prism shape, a hollow truncated polygonal pyramid shape, a hollow truncated cone shape, or a funnel shape; and an orthodontic wire that is inserted into the hollow portion of the orthodontic member, wherein the orthodontic member includes a water-soluble or biodegradable material. Thereby, the orthodontic composite of the present invention making it simple to perform orthodontic treatment by attaching the orthodontic composite.

Disclosed is an orthodontic composite, comprising: an orthodontic member which has a tube shape, a hollow polygonal prism shape, a hollow truncated polygonal pyramid shape, a hollow truncated cone shape, or a funnel shape; and an orthodontic wire that is inserted into the hollow portion of the orthodontic member, wherein the orthodontic member includes a water-soluble or biodegradable material. Thereby, the orthodontic composite of the present invention making it simple to perform orthodontic treatment by attaching the orthodontic composite.

In some embodiments, apparatuses, and methods are provided herein pertaining to orthodontic devices. In some embodiments, a hybrid attachment for orthodontic use comprises a body, wherein the body comprises an archwire slot, wherein the archwire slot is configured to receive an archwire, a bonding surface, wherein the bonding surface is configured to bond to a facial surface of a patient's tooth via an adhesive, and wherein the bonding surface is located on a first side of the body, and a facial surface, wherein the facial surface has a nonnegative draft normal to the facial surface of the patient's tooth, wherein the facial surface is configured to releasably retain a removable orthodontic aligner, and wherein the facial surface is located on a second side of the body.

A method for directly printing orthodontic and dental appliances on the teeth of a patient. The tooth is scanned with a scanner which is communicated with a computer controller configured to recognize the anatomy of the tooth. The surface of a tooth of the patient is then prepared in order to receive the type of appliance designated for the patient. Using image data from the print head, the computer controller prepares a three-dimensional blueprint or design of an appropriate orthodontic or dental appliance. The computer controller controls the type and amount of material that is distributed through the print head only when the print head passes over the recognized anatomy so as to directly print the corresponding appliance onto the tooth layer by layer as the print head makes successive passes over the surface of the tooth.

A method for directly printing orthodontic and dental appliances on the teeth of a patient. The tooth is scanned with a scanner which is communicated with a computer controller configured to recognize the anatomy of the tooth. The surface of a tooth of the patient is then prepared in order to receive the type of appliance designated for the patient. Using image data from the print head, the computer controller prepares a three-dimensional blueprint or design of an appropriate orthodontic or dental appliance. The computer controller controls the type and amount of material that is distributed through the print head only when the print head passes over the recognized anatomy so as to directly print the corresponding appliance onto the tooth layer by layer as the print head makes successive passes over the surface of the tooth.

Dental apparatuses, such as palatal expanders, and methods of forming them. The dental apparatuses may have multiple regions having different physical characteristics for performing different functions when worn by a patient as part of a dental treatment. The different regions may be made of different materials, or different combinations of materials, based on rigidity, flexibility and/or other physical characteristics. For palatal expanders, the different regions can include a tooth engagement region adapted to engage with the patient's teeth and a palatal region adapted to exert an expansion force across the patient's palate. The different regions may be joined together by a junction or a transition region configured to sufficiently hold adjacent regions together during use.

Dental apparatuses, such as palatal expanders, attachment templates, mandibular repositioning aligners, and a variable property aligners, and methods of forming them. The dental apparatuses may have multiple regions having different physical characteristics for performing different functions when worn by a patient as part of a dental treatment. The different regions may be made of different materials, or different combinations of materials, based on rigidity, flexibility and/or other physical characteristics. The different regions may be joined together by a junction region configured to sufficiently hold adjacent regions together during use.

Dental apparatuses, such as palatal expanders, attachment templates, mandibular repositioning aligners, and a variable property aligners, and methods of forming them. The dental apparatuses may have multiple regions having different physical characteristics for performing different functions when worn by a patient as part of a dental treatment. The different regions may be made of different materials, or different combinations of materials, based on rigidity, flexibility and/or other physical characteristics. The different regions may be joined together by a junction region configured to sufficiently hold adjacent regions together during use.