An optical scanning imaging/projection apparatus includes a light source that outputs illumination light and projection light in the visible range, an optical scanner that scans the illumination light and the projection light, which are output from the light source, along a predetermined scanning trajectory, a switch that switches the output from the light source so that the illumination light and the projection light are alternately output, an optical detector that detects observation light generated by a subject irradiated with the illumination light, a storage that stores data in which an intensity of the detected observation light detected is associated with information indicating a detection position on the scanning trajectory, and a projection light controller that controls, on the basis of the data stored in the storage unit, an intensity of the projection light to be applied to each position on the scanning trajectory.

Methods and apparatuses for taking, using and displaying three-dimensional (3D) volumetric models of a patient's dental arch. A 3D volumetric model may include surface (e.g., color) information as well as information on internal structure, such as near-infrared (near-IR) transparency values for internal structures including enamel and dentin.

An endoscope may include a shaft having a longitudinal axis, a first image sensor facing a distal direction, and a second image sensor facing a lateral direction. The endoscope may further include a tubular member having a lumen, the lumen having a distal-end opening and defining a longitudinal axis through a center of the lumen. The tubular member may be movable between a first configuration and a second configuration. In the first configuration of the tubular member, the longitudinal axis of the lumen may be parallel to the longitudinal axis of the shaft. In the second configuration of the tubular member, the longitudinal axis of the lumen may extend through a lateral opening in a wall of the shaft.

The disclosed technology is directed to an endoscope processor used in an endoscope system which comprises a receptacle configured to receive a plug of an endoscope. The plug includes an illumination plug terminal, an electric plug terminal, and a light-receiving plug terminal. The receptacle includes an illumination receptacle terminal that is displaceable within a predetermined range in a housing for the receptacle and is to be connected to the illumination plug terminal. An electric receptacle terminal is displaceable within a predetermined range in the housing and is to be connected to the electric plug terminal. A light-receiving receptacle terminal that is arranged between the illumination receptacle terminal and the electric receptacle terminal, is attached relative to the housing and is to be connected to the light-receiving plug terminal.

A sensor probe has a sensor unit which is embedded in a sheath member which is suturable. The sheath member allows the sensor unit to be sutured and secured to any tissue even in a wet or moist environment. The sensor probe in accordance with the present invention is particularly useful as an intraoral sensor probe for measuring oxygen saturation of a flap tissue inside the oral cavity.

A video endoscope with lateral viewing direction including a shaft having proximal and distal ends, an objective lens in the distal end, an image sensor, and a main body at the proximal end. Where a first grip rotationally fixed relative to the shaft and the main body to rotate the shaft and the main body to change the viewing direction of the objective lens. A second grip is disposed on the main body to be rotatable relative to the shaft and the main body to maintain a horizontal position of the image sensor when the viewing direction is changed. An annular seal is disposed between the second grip and the main body and/or the first grip. The seal includes a circumferentially wound coil spring having windings oriented such that a surface vector of a surface spanned by a single winding points substantially in a circumferential direction of the seal.

An optical fiber scanning device includes a housing, an optical fiber configured to emit light, a magnet disposed on the optical fiber, four drive coils configured to drive the optical fiber by applying to the magnet a magnetic field generated by a received drive power signal, and four detection coils configured to output an induced electromotive force signal corresponding to variation of a magnetic field, wherein the drive power signal is controlled based on the induced electromotive force signal, and four coil assemblies each including any one of the drive coils and any one of the detection coils are disposed at rotationally symmetrical positions so as to interpose the optical fiber among the four coil assemblies.

A multi-photon optical probe includes a probe housing, a lateral scanning stage coupled to a lateral mirror assembly and a remote axial scanning stage coupled to an axial mirror assembly. The lateral scanning stage is adapted to scan output laser energy over a planar scan area of the sample by moving the lateral mirror assembly. The axial scanning stage is adapted to scan the output laser energy over a vertical depth range of the sample, which, combined with the planar scan area, forms a 3-dimensional volume. A controller operates in conjunction with a number of remote actuating legs coupled to the axial mirror assembly in order to provide level imaging plane which in turn provides for a clear scanned image.

A method includes receiving scan data of a tooth during a first mode of operation, the scan data of the tooth having been generated by an intraoral scanner. The method includes invoking a second mode of operation and presenting, in a GUI, an image of the tooth. The method includes presenting, in the GUI, indications of a plurality of color zones of the tooth, the indications comprising, for at least one color zone of the plurality of color zones, an indication that insufficient color information has been received, wherein each color zone represents a separate region of the tooth for which an approximately uniform color is to be used. The method includes categorizing, for one or more color zones of the plurality of color zones for which sufficient color information has been received, each of the one or more color zones according to a color pallet used for dental prosthetics.

An optical probe imaging system includes an optical probe with a multicore optical fiber positioned therein. Distal optics are optically coupled to the distal end of the multicore fiber that image light propagating in the multicore fiber so as to generate a light pattern on a sample that is based on a relative position of at least two cores at a distal facet of the multicore fiber. A distal motor is mechanically coupled to the optical probe so that a motion of the distal motor causes the light pattern to traverse a path across the sample. An optical receiver is coupled to the proximal end of the multicore fiber and receives light that has traversed the path across the sample and then generates an electrical signal corresponding to the received light. A processor maps the electrical signal to a representation of information about the sample, wherein the mapping is based on the relative position of at least two cores at the distal facet of the multicore fiber and on the motion of the distal motor.