A method for detecting demineralization of a tooth substance, including the steps of irradiating (S101) a structured light pattern onto the tooth substance; detecting (S102) a light intensity of the light pattern remitted from the volume of the tooth substance; and determining (S103) demineralization of the tooth substance based on the detected light intensity.

An intraoral measurement device includes: a device main body that holds a base end side of a prism by a housing, the housing accommodating an illumination member and an imaging member, a cover member that is attached to the device main body in a state of covering, with a space part interposed in between, a distal end side of the prism arranged to face a measurement target, in which a part arranged to face the measurement target is formed by a light transmission window; and a heat transfer member that extends from the device main body along a non-optical surface of the prism, and transfers heat of the device main body to the light transmission window through abutment of a protruding end provided to protrude from the prism against the light transmission window of the cover member.

A dental and facial imaging device includes an adjustable arm, an image sensor mounted on a first end of the adjustable arm and an adjustable patient positioning arm mounted on a second end of the adjustable arm. A distance between the adjustable patient positioning arm and the image sensor is adjustable based on an adjustable length of the adjustable arm. A position indicator scale of the adjustable arm includes multiple notches for calibrating the distance between the adjustable patient positioning arm and the image sensor. The adjustable patient positioning arm includes a patient teeth supporting device and a patient chin rest which are positioned at a fixed coordinate reference relative to the image sensor to capture an image of a patient's teeth. The fixed coordinate reference corresponds to co-ordinates of multiple anatomical planes associated with the patient teeth supporting device and a patient chin rest relative to the image sensor.

A method for acquiring image data obtains, for an intraoral feature, optical coherence tomography (OCT) data in three dimensions wherein at least one dimension is pseudo-randomly or randomly sampled and reconstructs an image volume of the intraoral feature using compressive sensing, wherein data density of the reconstructed image volume is larger than that of the obtained OCT data in the at least one dimension or according to a corresponding transform. The method renders the reconstructed image volume for display.

The present invention discloses an oral scanner, including an outer casing, a reflector, a heat source, an optical module and a forced convection element. The outer casing has a cavity. The reflector is located at the front end of the cavity. The heat source is located in the outer casing. The optical module is located in the casing. A heat channel is formed between the optical module and the outer casing. The forced convection element is disposed in the heat channel and configured to forcedly dissipate the waste heat of the heat source to the cavity to heat the reflector. Thus, the temperature of the heat source can be reduced, and vapor will not be generated on the reflector heated by the waste heat.

A method (500) for localizing gingival inflammation using an oral care device (10), the method comprising: (i) emitting (520) light at a first intensity by a light emitter (42); (ii) obtaining (530) first reflectance measurements reflectance data; (iii) determining (540), by a controller (30) from the first reflectance data, whether the location comprises gingiva; (iv) automatically adjusting (550), based at least in part on the first reflectance data, the intensity of a light emitter to a second intensity different from the first intensity, and/or automatically adjusting (550) a gain of a light detector; (v) obtaining (560) a second plurality of reflectance measurements by the light detector of the oral care device for at least some of the locations; and (vi) determining (570), using the second plurality of reflectance measurements, whether gingiva at the location is inflamed.

An intraoral scanner generates 2D images of a dental site and 3D intraoral scans of the dental site. The computing device receives the 2D images of the dental site and the 3D intraoral scans of the dental site from the intraoral scanner, generates a 3D model of the dental site based on the 3D intraoral scans of the dental site, and processes at least one of a) one or more of the 2D images of the dental site, b) one or more of the 3D intraoral scans of the dental site, or c) data from the 3D model of the dental site to identify one or more intraoral areas of interest (AOIs) at the dental site. The computing device determines a dental condition associated with the one or more intraoral AOIs, and determines a manner for scanning the one or more intraoral AOIs.

Provided is a tooth analysis server including: a server communication unit linked with a tooth photographing device for photographing teeth to communicate with a user terminal; a database management unit for managing an image of the photographed teeth as data; an analysis unit for analyzing a state of the teeth of the user according to the request; and a result providing unit for providing an analysis result for the state of the teeth of the user to the user terminal, wherein the analysis unit receives a first image obtained by photographing the teeth of the user at a first speed from the tooth photographing device to perform a first analysis, and receives a second image obtained by photographing the doubtful area at a second speed slower than the first speed from the tooth photographing device to perform a second analysis.

The present invention relates generally to a system and method for measuring the structural characteristics of an object. The object is subjected to an energy application processes and provides an objective, quantitative measurement of structural characteristics of an object. The system may include a device, for example, a percussion instrument, capable of being reproducibly placed against the object undergoing such measurement for reproducible positioning. The system does not include an external on/off switch or any remote on/off switching mechanism. The system also includes a disposable feature or assembly for minimizing cross-contamination between tests. The structural characteristics as defined herein may include vibration damping capacities, acoustic damping capacities, structural integrity or structural stability.

A dental tool electrically powered by a power source includes: a handpiece having at least one switch; and a probe attachable to the handpiece so as to define a probe tip, the dental tool being operable to maintain the probe at its probe tip at a specifiable temperature. At least one of the handpiece and the probe includes a thermoelectric device, the dental tool being operable to maintain the probe at said probe tip at a specifiable temperature in response to user actuation of the at least one switch. Optionally, a second handpiece having an electrically conductive enclosure houses a second switch held by the patient. A method of conducting a dental test on a tooth of the patient includes: generating a sensory stimulus at the probe tip when the probe tip is in contact with the tooth; and receiving an actuation by the patient of the second switch.