A device includes a mounting platform selected from an eyeglass frame, a visor, a hat, a headlamp strap, a spectrally tunable lighting module adjustably mounted to the mounting platform and configured to illuminate an area based on one or more predetermined lighting commands, adjust one or more spectral characteristics of light emitted by an LED module of the head-mounted device in response to receiving the one or more predetermined lighting commands, wherein the LED module includes a plurality of LEDs selected from the group consisting of cool white LEDs, warm white LEDs, red LED, green LED, blue LED, and combinations thereof, and a hands-free interface that communicates the one or more predetermined lighting commands for one or more procedures to be performed to the head-mounted device. A system and computer program for use with the device are disclosed.

Provided is an inner bite ring which can be used by wearing a glove on a finger wearing the inner bite ring, is unlikely to damage the glove, and does not damage tissue around an oral cavity or teeth even if it is bitten from over the glove, for maintaining an opening and guarding the finger. An inner bite ring 1 has: a tubular portion 2 into which a finger of a human hand is inserted, the glove being worn on the inner bite ring 1 worn on the finger; a soft elastic portion 3 coated on an outer periphery of the tubular portion 2; and a strap portion 4 connected to a root portion 2b side of the tubular portion 2 and hung on a wrist or an adjacent finger. The tubular portion 2 is closed at its tip, and has a vent hole 6 formed on a tip portion side to communicate an inside and an outside of the tubular portion 2.

A dental bite block device includes a front wall, a flat lateral sidewall, and a concave lateral sidewall that define a longitudinal channel that extends through the device. The lateral sidewalls are connected by a crossbar, and the channel can be filled with polyvinyl siloxane (PVS) dental impression putty. When the device is positioned in the patient's mouth, the flat lateral sidewall faces the right inner check of the patient, the patient's tongue rests against the concave lateral sidewall, and the patient's upper and lower teeth rest open on the front wall. Once the PVS putty sets, it forms a solid half cylinder-shaped member that includes impressions of a plurality of the patient's upper and lower teeth, which assist to maintain the device in place. The front wall and concave sidewall further include an opening that defines a clip for a saliva ejector.

A curing light may include a housing sized and configured for placement over a tooth. A first facet positioned within the housing may have a first LED mounted thereon, a second facet positioned within the housing may have a second LED mounted thereon, and a third facet positioned within the housing may have a third LED mounted thereon.

The specification discloses a dental curing light including 1) a light engine, 2) a coaxially aligned, camera-based viewing system, and 3) a control system providing a variety of safety features and simplified, operator-friendly operation. The camera's field of view (FOV) is coaxial with the centerline of the curing beam of the light engine. The curing light includes a multi-planar dichroic mirror (MDM) providing viewing and light beam direction aligned with the target. The MDM provide multiple images to the camera from different angles. The camera provides real-time measurement of light intensity reflected back from the targeted surface. Using the multiple image portions reflected by the multi-planar dichroic mirror, the control system computes the distance between the curing light and the target. The reflected intensity and the calculated distance enable the control system to compute a light engine irradiance to achieve a desired irradiance at the targeted surface.

The specification discloses a dental curing light including 1) a light engine, 2) a coaxially aligned, camera-based viewing system, and 3) a control system providing a variety of safety features and simplified, operator-friendly operation. The camera's field of view (FOV) is coaxial with the centerline of the curing beam of the light engine. The curing light includes a multi-planar dichroic mirror (MDM) providing viewing and light beam direction aligned with the target. The MDM provide multiple images to the camera from different angles. The camera provides real-time measurement of light intensity reflected back from the targeted surface. Using the multiple image portions reflected by the multi-planar dichroic mirror, the control system computes the distance between the curing light and the target. The reflected intensity and the calculated distance enable the control system to compute a light engine irradiance to achieve a desired irradiance at the targeted surface.

A process for determining a tooth color of a filling or another restoration is provided which in particular is produced using composite materials, wherein at least one tooth is scanned or is visually detected. The process is characterized in that natural teeth are spectrally measured in advance, that the color values measured within a color space are classified into several, in particular four, categories which each form a color cloud extending in a three-dimensional fashion within the color space, which is done with the help of a structuring algorithm, in particular a Nearest Neighbour Algorithm, or a symmetry recognition algorithm, and that the tooth color of the filling is determined by means of evaluating to which category the tooth scanned has the smallest color distance, or to which color cloud the tooth scanned belongs.

Disclosed is a vibration apparatus for dental care including a body in which a vibrator is embedded; a tip part connected to the body to extend to an outside of the body and configured to transmit vibration energy of the vibrator to a resin applied to a tooth; and a controller configured to control a magnitude of vibration energy generated from the vibrator and transmitted to the tip part, wherein the controller controls a vibration frequency of the tip part within a range of 3 to 70 Hz. According to such configuration, the viscosity of resin attached to a tooth is lowered so that the resin can be easily formed into a desired shape and the tooth can be treated without generation of voids in the resin.

Disclosed is a vibration apparatus for dental care including a body in which a vibrator is embedded; a tip part connected to the body to extend to an outside of the body and configured to transmit vibration energy of the vibrator to a resin applied to a tooth; and a controller configured to control a magnitude of vibration energy generated from the vibrator and transmitted to the tip part, wherein the controller controls a vibration frequency of the tip part within a range of 3 to 70 Hz. According to such configuration, the viscosity of resin attached to a tooth is lowered so that the resin can be easily formed into a desired shape and the tooth can be treated without generation of voids in the resin.

A borate bioactive glass is described, and may be used in the form of particles in an acidic mixture to form a borate bioactive glass paste. The borate bioactive glass paste may be used for the restoration of dentin and enamel on a tooth surface by the precipitation of calcium phosphate. The borate bioactive glass may also be used as a bone grafting material.