Imaging methods aid a user in understanding relative depths of objects or topography within a field of view. In one method, image data is gathered using 3D image sensors, while illumination of an area of interest is alternated with projection of a pattern onto the area of interest. The captured image data is used to display a 3D true color image; a monochrome grid on surfaces of the area of interest; a 3D true color image with a monochrome grid on surfaces of the area of interest; a 2D or 3D false color image where different colors identify different depths of regions of the area of interest; and/or a 2D or 3D true color image of an area of interest with features in the area of interest located a first depth relative to the image sensors highlighted with a common color. In another method, 3D image data is used to generate a 2D image that highlights features at a common depth using the same color.

Methods and systems are described that receive intraoral scan data in response to an optical scan of a surface of the tooth and a material disposed between the tooth and a gingiva surrounding the tooth, the material separating the surrounding gingiva from the tooth and covering a sub-gingival surface of the tooth. The received intraoral scan data is processed to differentiate the first optical scan data associated with the sub-gingival surface of the tooth and the second optical scan data associated with the material covering the sub-gingival surface of the tooth. The three-dimensional model of the tooth is generated based on the first optical scan data that is associated with the sub-gingival surface of the tooth and the third optical scan data associated with the tooth surface that is not covered by the material such that the three-dimensional model of the tooth includes the sub-gingival surface of the tooth.

Endoscopic imaging systems are disclosed herein. In some embodiments, an endoscopic imaging system can include an endoscope having a distal tip with a distal face configured to face a scene, such as a portion of a body cavity of a patient. The endoscope can further include first cameras for capturing first image data of the scene, a projector for projecting a light pattern into the scene, and second cameras for capturing second image data of the scene including the light pattern. A processor can be communicatively coupled to the first and second cameras for receiving the first and second image data. The processor can process the first and second image data to generate an image of the scene at the perspective of a virtual camera, and can vary the perspective, the aperture, the focus plane, and/or another parameter of the virtual camera without requiring the endoscope to be physically moved.

Techniques for detecting depth contours of an anatomical target and for enhancing imaging of the anatomical target are provided. In an example, a reference pattern of light can be projected across an anatomical target and an image of the reflected light pattern upon the anatomical target can be captured. The captured light pattern can be analyzed to determine contour information, which can then be used to provide 3D cues to enhance a 2-dimensional image of the anatomical target.

A device to check the quality and dosage of anesthetic dispensing device that is used for the application of anesthetic fluids using a spray nozzle is provided. This device can be adapted for use in the oral cavity and upper tracheal area of a medical patient prior to intubation of such patient. The present device comprises of a camera system, a stroboscopic lighting system, and an image analysis software.

In a system and method for assessing tissue excision comprise, first 3-dimensional data is acquired for a surgical region of interest from which tissue is to be excised, the first data defining initial geometry of tissue in the region of interest. A desired excision parameter, such as depth or shape, is determined and tissue is excised from the region of interest. Second 3-dimensional data for the region of interest is then acquired, the second scan data defining post-excision geometry of the tissue in the region of interest. The first and second data is compared to determine whether the desired excision parameter has been reached. The 3-dimensional data may be scan data acquired using a 3D or 2D endoscope, and/or it may be derived from kinematic data generated as a result of moving an instrument tip over the region of interest.

A method for generating and updating a three-dimensional representation of a surgical site based on imaging data from an imaging system is disclosed. The method comprises the steps of generating a first image of the surgical site based on structured electromagnetic radiation emitted from the imaging system, receiving a second image of the surgical site, aligning the first image and the second image, generating a three-dimensional representation of the surgical site based on the first image and the second image as aligned, displaying the three-dimensional representation on a display screen, receiving a user selection to manipulate the three-dimensional representation, and updating the three-dimensional representation as displayed on the display screen from a first state to a second state according to the received user selection.

A method for generating and updating a three-dimensional representation of a surgical site based on imaging data from an imaging system is disclosed. The method comprises the steps of generating a first image of the surgical site based on structured electromagnetic radiation emitted from the imaging system, receiving a second image of the surgical site, aligning the first image and the second image, generating a three-dimensional representation of the surgical site based on the first image and the second image as aligned, displaying the three-dimensional representation on a display screen, receiving a user selection to manipulate the three-dimensional representation, and updating the three-dimensional representation as displayed on the display screen from a first state to a second state according to the received user selection.

A method for generating and updating a three-dimensional representation of a surgical site based on imaging data from an imaging system is disclosed. The method comprises the steps of generating a first image of the surgical site based on structured electromagnetic radiation emitted from the imaging system, receiving a second image of the surgical site, aligning the first image and the second image, generating a three-dimensional representation of the surgical site based on the first image and the second image as aligned, displaying the three-dimensional representation on a display screen, receiving a user selection to manipulate the three-dimensional representation, and updating the three-dimensional representation as displayed on the display screen from a first state to a second state according to the received user selection.

A method for generating and updating a three-dimensional representation of a surgical site based on imaging data from an imaging system is disclosed. The method comprises the steps of generating a first image of the surgical site based on structured electromagnetic radiation emitted from the imaging system, receiving a second image of the surgical site, aligning the first image and the second image, generating a three-dimensional representation of the surgical site based on the first image and the second image as aligned, displaying the three-dimensional representation on a display screen, receiving a user selection to manipulate the three-dimensional representation, and updating the three-dimensional representation as displayed on the display screen from a first state to a second state according to the received user selection.