Abstract: A dual-purpose Oral Appliances having smart sensors and control module for treating sleep apnea and simultaneously straightening the teeth or reducing the bruxism or reducing the TMJ disorder are disclosed. The appliance contains upper and or lower teeth trays with or without air passageway. The appliance can be with or without external housing. The episodes of sleep apnea are reducing by one or combination of several mechanisms such as mandibular advancement (MAD), air stimulation by control of inhaled air flow bypassing the tongue and or micro-holes in air passageways, neuro/muscle electric stimulation of tongue and sleep position training. The sensors located inside or outside of the mouth, measure physiological and or biological and or chemical aspects of the patients. The sensors are connected to control module system consists of battery, microprocessor, and data transmission technologies.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors divots are provided. An example process generates multiple virtual models of orthodontic treatment based on progressive moduli of elasticity (MOE) of different materials that will be used to 3D-print a progressive set of 3D-printed aligners. A progression of 3D-printed aligners applies modeled forces to the divot anchors positioned by the models and to the teeth, in treatment stages that are also computed by the models. One class of the example 3D-printed aligners may have flat occlusal biting surfaces, enabling simultaneous treatment of bite correction, temporomandibular joint disorder (TMD), lower jaw growth, and sleep apnea, along with orthodontic movement of teeth. An example 3D-printed aligner has a micro blower for creating air pressure to treat apnea. The aligner may have a microprocessor, sensors, data handling, and data transmission, for controlling actions of the 3D-printed aligner.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors divots are provided. An example process generates multiple virtual models of orthodontic treatment based on progressive moduli of elasticity (MOE) of different materials that will be used to 3D-print a progressive set of 3D-printed aligners. A progression of 3D-printed aligners applies modeled forces to the divot anchors positioned by the models and to the teeth, in treatment stages that are also computed by the models. One class of the example 3D-printed aligners may have flat occlusal biting surfaces, enabling simultaneous treatment of bite correction, temporomandibular joint disorder (TMD), lower jaw growth, and sleep apnea, along with orthodontic movement of teeth. An example 3D-printed aligner has a micro blower for creating air pressure to treat apnea. The aligner may have a microprocessor, sensors, data handling, and data transmission, for controlling actions of the 3D-printed aligner.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors are provided. In an implementation, an orthodontic system uses 3D-printed aligners to perform orthodontic treatment of teeth. Manufacturing the aligners by 3D-printing or additive manufacturing processes imparts novel geometries to the aligners for applying torque, rotation, and full 3D control forces to the teeth in novel ways. The 3D-printed aligners may contain multiple different plastic or metal materials with different orthodontic properties. In an implementation, divot anchors can be strategically applied to teeth to work in conjunction with a 3D-printed aligner fitted over the divot anchors and teeth. The divot anchors may include a depression, channel, groove, or notch providing an attachment point for the aligner to apply a force to the tooth through the divot anchor, such as a torque, rotational force, leverage, push, pull, or 3D control force.