Abstract: Methods and systems are described for operating an intra-oral imaging sensor that includes a housing, an image sensing component at least partially housed within the housing, and a magnetometer at least partially housed within the housing. An output of the magnetometer indicative of an actual magnetic field that impinges the intra-oral imaging sensor is compared to data indicative of a first expected magnetic field. In response to determining, based on the comparison, that the actual magnetic field matches the first expected magnetic field, the electronic processor alters the operation of the imaging system. In some embodiments, the electronic processor causes the intra-oral imaging sensor to operate in a low-power state in response to determining that the actual magnetic field matches a first expected magnetic field indicative of placement of the intra-oral imaging sensor in an imaging sensor storage compartment.

Abstract: An imaging system, a method for imaging an object of interest, and an image of the object of interest. In one embodiment, an imaging system includes a channel configured to receive information from an object of interest, a 3DSS sub-system configured to capture information from the object of interest and generate at least one of 3D surface data or 3D position data based on the information captured by the 3DSS sub-system, and an OCT sub-system configured to perform a line scan of light reflected from the object of interest, generate OCT image data from the line scan, receive the at least one of the 3D surface data or the 3D position data, and generate one or more OCT images using the OCT image data and the at least one of the 3D surface data or the 3D position data.

Abstract: Technology is described for generating a design for a dental restorative product from one or more dental images of a patient. The method can include obtaining a three-dimensional (3D) image of dentition of the patient prior to a change in dentition of the patient; and then determining the change in dentition of the patient. A design of a dental restorative product can be automatically generated for at least one tooth of the patient based on the 3D image of dentition prior to the change in dentition. Various other computer-implemented methods, systems, and computer-readable media are also disclosed.

Abstract: Methods and systems are described for removing reflective artifacts from an imaging model. An x-ray detector captures x-ray images that include a structure and an imaging device captures a surface scan of the same structure. An image processor constructs a three-dimensional CT model of the structure from the x-ray images and constructs a three-dimensional surface model of the structure from the surface scan. The image processor is configured to resize and orient the surface model and/or the CT model so that they are the same scale and orientation, overlay the surface model onto the CT model, and detect data points in the combined data set that extend beyond a surface of the structure in the surface model. The detected data points represent artifacts in the CT model and are adjusted by interpolation to produce an artifact-reduced CT model.

Abstract: Systems and methods are presented for assisting in providing consistent alignment of a handheld intra-oral imaging device for a series of images. Live image data of the patient is received from the intra-oral image capture device and displayed on the display. A previously stored intra-oral image of the patient is accessed from the non-transitory memory and an alignment mask is generated based on the accessed previously stored intra-oral image. The alignment mask is displayed on the display overlaid onto the live image data. The system captures a new intra-oral image of the patient from the live image data and stores the new intra-oral image to the non-transitory memory.

Abstract: A visualization system for displaying volumetric renderings includes a display, a user input actuator that is movable over a first range, a second range, and a third range, and a processor. The second range is located between the first range and the third range. The processor is configured to generate a first volumetric rendering according to a first transfer function when the user input actuator is positioned in the first range, and generate the first volumetric rendering according to a second transfer function when the user input actuator is positioned in the third range. The second transfer function is different than the first transfer function. The processor is further configured to generate the first volumetric rendering according to a blending of the first transfer function and the second transfer function when the user input actuator is positioned in the second range, and display the first volumetric rendering on the display.

Abstract: Methods, systems, and devices for determining characteristics of an intraoral dental imaging sensor. A method includes providing an intraoral dental imaging sensor having a housing and a magnetic field sensor disposed in or on the housing, placing the intraoral dental imaging sensor in a holder, positioning the intraoral dental imaging sensor and at least part of the holder in a mouth of a patient, attaching a reference magnet to the patient, receiving, by an electronic processor, magnetic field data from the magnetic field sensor, determining, by the electronic processor, information including a position of the intraoral dental imaging sensor in the mouth of the patient based at least in part on the magnetic field data, and detecting x-rays by the intraoral dental imaging sensor to produce image data.

Abstract: Described are embodiments of methods of obtaining three-dimensional (3D) surface data of an object scene such as an intra-oral cavity. For example, measured surfaces may include the enamel surface of teeth, the dentin substructure of teeth, gum tissue and various dental structures. The methods can also be applied in medical applications and other applications in which 3D measurement data are acquired with maneuverable 3D measurement devices. In certain embodiments, the measurement device is positioned and translated to enable 3D data to be acquired for a backbone 3D data set. Subsequent controlled motion of the measurement device enables additional 3D data to be acquired and accurately joined to the backbone 3D data set.

Abstract: Methods and systems for storing and accessing dental images. The system includes an imaging system for acquiring x-ray projection frames. The imaging system is connected to a local server through a local area network. A cloud server communicates with devices on the local area. The x-ray projection frames are transmitted from the imaging system to the local server. The local server stores the series of related x-ray projection frames according to a specified policy. In one embodiment, the x-ray projection frames are compressed into a compressed image data set using a modified video compression prediction algorithm customized for x-ray images. The x-ray image data (whether compressed or not) is transmitted to the cloud server for storage. The x-ray image data can be accessed from the cloud server by external devices and by other local area networks.

Abstract: Methods and systems for operating x-ray system. One system includes an x-ray source having a plurality of exposure parameters and a controller for the x-ray source. The controller for the x-ray source is configured to receive image characteristic information and automatically adjust the plurality of exposure parameters based on the image characteristic information. The image characteristic information can include an identifier of a predefined sequence of images, an identifier of an image type, a set of values of the plurality of exposure parameters, and a unique identifier of a holder for an x-ray receptor.

Abstract: Methods and systems are described for removing reflective artifacts from an imaging. A first volumetric model and a second volumetric model of the same object are accessed from a computer-readable memory. The orientation and scale of at least one of the two models is repeatedly and automatically adjusted until an optimized orientation and scale is determined that correlates the first volumetric model and the second volumetric model. The second volumetric model is then overlaid onto the first volumetric model. Any data points in the first volumetric model that extend beyond a surface of the second volumetric model are detected and removed to create an artifact-reduced volumetric model.

Abstract: A method and a system for correcting and reconstruing a plurality of projection images based on detected patient motion. The method includes obtaining a plurality of projection images generated by a scanner. Each of the plurality of projection images includes at least three markers. Each of the at least three markers has a measured three-dimensional position and measured positions on a detector panel of the scanner in a first dimension and a second dimension. The method further includes determining a position error vector for each of the plurality of projection images based on the at least three markers in each of the plurality of projection images, the position error vector defining patient motion in the projection image.

Abstract: Devices, methods, and systems including an intraoral x-ray imaging sensor. The intraoral x-ray imaging sensor having a substrate having an imaging area and a non-imaging area, a plurality of readout amplifiers located in the non-imaging area of the substrate, an array of pixels located on the imaging area of the substrate and arranged as a plurality of rows and columns, and pixel selector circuitry diagonally arranged in the imaging area of the substrate. Each pixel of the array of pixels is selectively coupled to one or more of the plurality of readout amplifiers.

Abstract: Systems and methods are presented for evaluating a dental condition. A first digital representation of at least a portion of an oral cavity of a first patient is compared to a second digital representation of the oral cavity of the same patient. The first digital representation is representative of the oral cavity of the first patient at a first time and the second digital representation is representative of the oral cavity of the first patient at a second, later time. At least one clinically-significant difference between the first digital representation and the second digital representation are automatically identified and the first digital representation is displayed in a way that highlights the at least one clinically significant difference.

Abstract: A method and a system for correcting and reconstruing a plurality of projection images based on detected patient motion. The method includes obtaining a plurality of projection images generated by a scanner. Each of the plurality of projection images includes at least three markers. Each of the at least three markers has a measured three-dimensional position and measured positions on a detector panel of the scanner in a first dimension and a second dimension. The method further includes determining a position error vector for each of the plurality of projection images based on the at least three markers in each of the plurality of projection images, the position error vector defining patient motion in the projection image.

Abstract: Methods and systems for viewing images. One system includes a source of images, a computer, and a screen. The computer is configured to generate a graphical user interface or GUI. The GUI includes a first window in which one or more of the images are displayed. The GUI is displayed on the screen and the graphical user interface module generates an output or modifies the GUI in response to user input (e.g., tap, click, etc.). In response to the input, the graphical user interface generates an image-navigation map. The image-navigation map is displayed in a foreground of the first window and the one or more images are in displayed in a background of the first window. The image-navigation map includes one or more thumbnail images of at least one of the one or more images.

Abstract: Methods and systems are described for removing reflective artifacts from an imaging model of a patient's teeth. A first volumetric model and a second volumetric model of the patient's teeth are accessed from a computer-readable memory. The orientation and scale of at least one of the two models is repeatedly and automatically adjusted until an optimized orientation and scale is determined that correlates the first volumetric model and the second volumetric model. The second volumetric model is then overlaid onto the first volumetric model. Any data points in the first volumetric model that extend beyond a surface of the patient's teeth in the second volumetric model are detected and removed to create an artifact-reduced volumetric model.

Abstract: A hybrid x-ray device for mounted and portable use. The hybrid x-ray device can include a housing, an x-ray source, a support connector, a shield connector, and an interlock. The x-ray source is coupled to the housing and configured to generate x-ray radiation. The support connector is coupled to the housing and configured to mechanically couple to a support arm. The shield connector is coupled to the housing and configured to mechanically couple to a removable radiation shield. The interlock is coupled to the x-ray source and configured to disable activation of the x-ray source when both: (a) the support connector is mechanically uncoupled from the support arm, and (b) the shield connector is mechanically uncoupled from the removable radiation shield.

Abstract: An intraoral x-ray sensor including a sensor housing and a universal serial bus (USB) data cable. The sensor housing has an opening. The USB data cable includes an outer sheath and a first data line, a second data line, a ground line, a power line, and at least two independent fillers positioned within the outer sheath. In one embodiment, at least two lines selected from the group including the first data line, the second data line, the ground line, and the power line are twisted together to form a single bundle. The opening receives the data cable.