An orthodontic appliance includes a portion made of a shape memory alloy having a base alloy composition of at least two different metallic elements and a treated region having an alloy composition that is depleted in at least one of the metallic elements. The base alloy may include a nickel titanium alloy (NiTi), a copper chromium nickel titanium alloy (CuCrNiTi), or a copper aluminum nickel (CuAlNi) alloy. The treated region may be depleted in at least one of copper, aluminum, nickel, and titanium relative to the base alloy composition by exposing the base alloy to a source of energy. The base alloy composition has a first austenitic finish temperature and the treated region has an austenitic finish temperature that may be different than the first austenitic finish temperature. The treated region may form a part of an archwire, a stop, a hook, a crown, a band, or an orthodontic bracket.

An orthodontic appliance includes a portion made of a shape memory alloy having a base alloy composition of at least two different metallic elements and a treated region having an alloy composition that is depleted in at least one of the metallic elements. The base alloy may include a nickel titanium alloy (NiTi), a copper chromium nickel titanium alloy (CuCrNiTi), or a copper aluminum nickel (CuAlNi) alloy. The treated region may be depleted in at least one of copper, aluminum, nickel, and titanium relative to the base alloy composition by exposing the base alloy to a source of energy. The base alloy composition has a first austenitic finish temperature and the treated region has an austenitic finish temperature that may be different than the first austenitic finish temperature. The treated region may form a part of an archwire, a stop, a hook, a crown, a band, or an orthodontic bracket.

An orthodontic bite ramp has a body having an anterior base for bonding attachment to the lingual surface of an upper tooth; an occlusal surface extending lingually from the base to provide a stop limiting upward movement of a patient's lower teeth; and a vertical slot in the lingual aspect of the bite ramp. The vertical slot divides the body into two lateral wings that can be compressed by application of a lateral compressive force to deform the base and thereby release the bite ramp from the tooth. Optionally, a bonding pad can be secured to the base for bonding attachment to the lingual surface of an upper tooth.

An orthodontic bite ramp has a body having an anterior base for bonding attachment to the lingual surface of an upper tooth; an occlusal surface extending lingually from the base to provide a stop limiting upward movement of a patient's lower teeth; and a vertical slot in the lingual aspect of the bite ramp. The vertical slot divides the body into two lateral wings that can be compressed by application of a lateral compressive force to deform the base and thereby release the bite ramp from the tooth. Optionally, a bonding pad can be secured to the base for bonding attachment to the lingual surface of an upper tooth.

A pocket orthodontic bonding pad for attaching orthodontic attachments to teeth wherein the orthodontic attachment is mechanically secured within a bonding pad pocket with a design that allows a slight buffering flexibility under masticatory stress and ease of removal of the orthodontic attachment. Upon removal of locking tabs the orthodontic attachment may be removed with minimal force, and the remaining bonding pad polished from the teeth with ease, which is most advantageous for brackets that tend to break upon removal and create high stress forces upon tooth structure. The ease of removing orthodontic attachments allows maximum bonding strengths.

A pocket orthodontic bonding pad for attaching orthodontic attachments to teeth wherein the orthodontic attachment is mechanically secured within a bonding pad pocket with a design that allows a slight buffering flexibility under masticatory stress and ease of removal of the orthodontic attachment. Upon removal of locking tabs the orthodontic attachment may be removed with minimal force, and the remaining bonding pad polished from the teeth with ease, which is most advantageous for brackets that tend to break upon removal and create high stress forces upon tooth structure. The ease of removing orthodontic attachments allows maximum bonding strengths.

An adjustable bracket is disclosed, including a main body and rotor, wherein the main body includes a base body which is provided with a base groove; the rotor is provided with a rotor body and a cover, the top of the rotor body is provided with a bracket slot, the cover is adapted to cover the top of the rotor body and cover the top of the opening of the bracket slot, the rotor is adapted to be pivotably connected to the base body, and the base body is further provided with a positioning portion for securing the rotor. An orthodontics system with the bracket and an orthodontic method are also disclosed. The adjustable bracket according to the present disclosure can be adjustable in torque, tip and the direction of the torsion on the tooth, and it can achieve a good corrective effect by simple operation.

A kit for an orthodontic bracket, which includes at least a base plate and a flap that can be pivoted over the base plate, to which a flap directly or indirectly guided wire bow can be fastened. The kit includes a selection of base plates and flaps differing in size and shape. Base plates and flaps are produced from sheet metal by bending and stamping. The two parts can be connected to each other without a shaft by being pivoted in relation to each other.

An orthodontic bracket is provided, including a backend surface, a frontend surface, a first side surface, a second side surface, and a passageway. The backend surface is adapted for attachment and is opposite the frontend surface. The first and second side surfaces are connected between the backend surface and the frontend surface. The passageway extends from the first side surface to the second side surface. The cross-section of the passageway includes an access opening, an archwire slot, a path portion, and at least one rotation portion. The access opening is configured to allow the archwire to enter the passageway. The archwire slot is configured to receive the archwire. The path portion connects the access opening and the archwire slot. The rotation portion is provided in the path portion to allow the archwire to change its orientation.

A method of manufacturing customized ceramic labial/lingual orthodontic brackets by digital light processing, said method comprises measuring dentition data of a profile of teeth of a patient, wherein measuring dentition data is performed using a CT scanner or intra-oral scanner, based on the dentition data, creating a three dimensional computer-assisted design (3D CAD) model of the patient's teeth using reverse engineering, and saving the 3D CAD model on a computer, designing a 3D CAD bracket structure model for a single labial or lingual bracket structure, importing the 3D CAD bracket structure model into a Digital Light Processing (DLP) machine, directly producing the bracket by layer manufacturing.