The present invention provides an intraoral sensor that includes: a sensor panel generating an electrical signal by detecting X-rays; an elasticity-adjusting member disposed behind the sensor panel and limiting elasticity of the sensor panel; a wireless communication circuit disposed behind the elasticity-adjusting panel, transmitting the electrical signal generated by the sensor panel to an external console wirelessly, and receiving the electrical signal from the console wirelessly; and a battery module disposed behind the elasticity-adjusting member and supplying power.

Methods, devices, systems, and series of appliances are provided for dental implant positioning. One method for positioning an implant with dental treatment includes determining an implant location based on a virtual model of an optimized dental occlusion, moving one or more teeth using a first number of a series of dental appliances, from a first orientation to a second orientation, the second orientation exposing the implant location, placing an implant at the exposed implant location using a landmark included in at least one of the series of dental appliances, repositioning one or more teeth using a second number of the series of dental appliances, from the second orientation to a successive orientation.

Systems and methods include determining, by an appointment management system, a condition that an appointment to conduct an intraoral scan at an intraoral scanning site has been missed by a user, automatically generating a message to the user indicating that an at-home dental impression kit can be sent to the user based on determining that the appointment has been missed, and transmitting the automatically generated message to a communications device associated with the user.

A combination dental imaging system and dental practice management and charting system includes a dental imaging device, a dental practice management and charting system and a bi-directional communication interface which couples the dental imaging system to the dental practice management and charting system. The combination dental imaging system and dental practice management and charting system also includes a code generator, a translator and a correlator. The code generator generates an ADA CDT code. The translator translates the ADA CDT code into at least one property required by the dental imaging system in order to acquire dental images of a specific image type, format and quantity. The correlator correlates the dental images to be acquired by the dental imaging system to the ADA CDT code so that the dental images are acquired by having at least one property set.

Provided is an X-ray module assembly for a portable X-ray device, in which an X-ray tube is made of a carbon nano tube or a filament-type tube, preferably, a carbon nano tube, high-voltage capacitors and high-voltage diodes are arranged space-intensively, fine control of X-ray emission may be achieved by molding the above-configured X-ray module within a case having a reduced size and a reduced weight with thermosetting resin, preferably, epoxy-based resin, more preferably, soft epoxy-based resin, so that radiation exposure to a user may be minimized, power consumption may be greatly reduced, the X-ray module assembly may be downsized and lightened, an insulation effect is excellent, and the X-ray module assembly may be used semi-permanently. The X-ray module for a portable X-ray device includes an X-ray tube, a high-voltage transformer structure, a plurality of high-voltage capacitors, and a plurality of high-voltage diodes, and is fixedly supported by a tube guide.

A medical device for treating a skin of a patient includes: a radiation source configured to provide radiation; a collimator coupled to the radiation source; and an optical device for viewing a target area on the skin when a distal end of the medical device is covering the skin. A method of treating a skin of a patient includes: providing a treatment device having a distal end, a radiation source, and a collimator, wherein the distal end is configured for placement over the skin of the patient so that the skin of the patient is covered by the distal end of the treatment device; and providing an image of a target on the skin when the distal end of the treatment device is covering the skin of the patient.

A dental x-ray sensor holder 1 and sheath 4 for affixing a sensor to a backing plate 2 of the holder 1. The dental x-ray sensor holder 1 and sheath 4 generally includes a sensor holder 1 with a backing plate 2, having one or more spring arms 3, and affixed to or formed contiguously with a proximal end of a bite block 9 of the holder 1. It also includes a sensor sheath adapted to secure a sensor to the backing plate for X-ray acquisition.

Systems and methods relate to a mobile intraoral scanning site. The mobile intraoral scanning site includes a vehicle and one or more three-dimensional intraoral scanners provided on the vehicle and configured to perform intraoral dentition scans of users on the vehicle. The vehicle can include at least two compartments configured to be used as scan stations for performing the intraoral dentitions scans of the users on the vehicle. The vehicle can be retrofitted to be used for the mobile intraoral scanning site. The one or more three-dimensional intraoral scanners can be wall-mounted on the vehicle. The vehicle can be provided with an internet connection such that the intraoral dentition scans are uploaded to a cloud server via the internet connection. Messages can be sent to a plurality of individuals inviting the plurality of individuals to schedule an appointment to receive an intraoral dentition scan at the vehicle.

Methods, devices, systems, and series of appliances are provided for dental implant positioning. One method for positioning an implant with dental treatment includes determining an implant location based on a virtual model of an optimized dental occlusion, moving one or more teeth using a first number of a series of dental appliances, from a first orientation to a second orientation, the second orientation exposing the implant location, placing an implant at the exposed implant location using a landmark included in at least one of the series of dental appliances, repositioning one or more teeth using a second number of the series of dental appliances, from the second orientation to a successive orientation.

Teeth are screened for periodontal disease using digitized images manipulated and annotated on a processor. A digitized radiographic image of a tooth shows locations of a bone boundary and a cemento-enamel junction (CEJ) of the tooth. The digitized radiographic image is marked on the processor with a location on the bone boundary and with a pair of CEJ points at opposite ends of the CEJ visible in the radiograph. A ratio between (a) a distance between the bone boundary location and the adjacent CEJ point as numerator and (b) a distance between the CEJ points as denominator is calculated on the processor and compared with a threshold ratio-value for a corresponding tooth from a database accessible by the processor. A calculated ratio-value which is greater than the database threshold ratio-value is indicative of periodontal disease in the tooth. The probability of the correct diagnostic decision is determined by the relative magnitude of the calculated ratio-value and the threshold ratio-value.