A method for obtaining an intra-oral image, the method executed at least in part by a computer system, emits illumination from an intra-oral camera toward an object that is within the mouth of a patient, then obtains image data content of the object at an image sensor of the intra-oral camera. The image content obtained from the imaging sensor is displayed and one or more movement signals indicative of movement of the intra-oral camera along at least two of three mutually orthogonal axes is obtained. The one or more obtained movement signals are interpreted as an operator instruction corresponding to a predetermined movement pattern. At least the display of the image content is changed according to the operator instruction.

The present invention relates to an automatic oral sensor sterilizing and packaging system and, particularly, to an automatic oral sensor sterilizing and packaging system capable of automatically sterilizing an oral sensor and further packaging the oral sensor with disposable wrapping paper, comprising: a housing including a sterilization unit providing a sterilization region for sterilization of the oral sensor and/or a packaging unit providing a packaging region for packaging the oral sensor; and a transfer unit for making the oral sensor pass through at least one of the sterilization region and the packaging region.

An oral examination device including a lip shield, a nipple, and a camera. The lip shield defines a front side and back side. The nipple extends from the front side of lip shield. The nipple defines an interior cavity with an opening to the interior cavity provided from the rear of the lip shield. The camera is positioned in the interior cavity of the nipple.

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 for taking a scan of a patient's oral cavity for use in fabricating a dental prosthesis. Such methods may include providing a healing cap configured to be received within a subgingival void of a given tooth position, taking a first scan of the healing cap, wherein the first scan is taken outside of a patient's oral cavity, seating the healing cap, taking a second scan, which is an intraoral scan of the healing cap and surrounding surfaces once the healing cap is seated, taken inside the patient's oral cavity; and integrating the first scan of the healing cap with the intraoral second scan of the healing cap and the surrounding surfaces into an overall oral cavity scan. A third scan, (e.g., 3D cone beam scan), can also be taken, which is overlaid or otherwise integrated with the first and second scans, for use in fabrication of a dental prosthesis.

Intraoral tomosynthesis systems, methods, and computer readable media for dental imaging can include an x-ray source containing multiple focal spots spatially distributed on one or multiple anodes in an evacuated chamber, an x-ray detector for positioning inside a mouth of a patient, a device for determining imaging geometry of the intraoral tomosynthesis system; and control electronics configured to regulate the x-ray source, by sequentially activating each of the multiple focal spots, such that multiple two dimensional (2D) projection images of the mouth of the patient are acquired from multiple viewing angles. In some aspects, the device for determining the imaging geometry can comprise a plate connectedly attached to the x-ray detector, at least one light source connectedly attached to the x-ray source, and a camera configured to capture at least one light spot produced by a projection of at least one light beam onto the plate.

A medical radiology system comprises an external x-ray source (1) and a CMOS image sensor (2) that is connected via a USB link (4) by way of USB peripheral of a device (3) for digitally processing the image data of the sensor. A tracking device is placed on the USB link (4) in order to continuously read and decode the data transmitted over this link in a way that is transparent to the device and to the sensor, and to detect, in the transmitted data stream, one particular datum (XAMC=1) representing a signal indicating detection, by the sensor, that a sufficient dose of radiation has been received. On detection of this particular datum, the tracking device sends an electrical signal Stop-X to the radiation source, in order to stop the emission of the radiation. The system is especially suitable for taking dental radiology images with an intra-oral CMOS sensor.

A method, apparatus, system, and computer program for generating clinical information. Information indicating at least one clinical aspect of an object is received. Clinical information of interest relating to the at least one clinical aspect is generated from a plurality of projection images.

An intra-oral system comprising: an x-ray detector configured to detect extra-orally applied x-rays; and a saliva fluid sensing sub-system configured to sense saliva fluid within the oral cavity.

Disclosed is an intraoral dental x-ray imaging sensor holder for Wireless IntraOral x-ray imaging Sensors (“WIOS”). The holder secures in place the WIOS from the hump on the backside of the WIOS corresponding to the battery. The holder with the WIOS attached can be painlessly and comfortably positioned inside the dental arch, since there are no brackets holding the WIOS from its edges, but instead from the battery hump. Additionally, the WIOS can be secured on the holder in reverse (rotated by 180 degrees) thus adding flexibility and versatility during intraoral x-ray imaging.