A method, system and computer readable storage media for guiding an intra-oral scan utilizing augmented reality. By visualizing a scan strategy in a field of view of a clinician during an intra-oral scanning scan procedure, a need to monitor the progress of the intra-oral scan on a separate monitor may be eliminated or reduced in order to save time.

An autostereoscopic three-dimensional display system for surgical robotics has an autostereoscopic three-dimensional display configured to receive and display video from a surgical robotics camera, and a first sensor assembly and a second sensor assembly. A processor is configured to detect and track an eye position or a head position of a user relative to the display based on processing output data of the first sensor assembly, and to detect and track a gaze of the user based on processing output data of the second sensor assembly. The processor further is configured to modify or control an operation of the display system based on the detected gaze of the user. A spatial relationship of the display also can be automatically adjusted in relation to the user based on the detected eye or head position of the user to optimize the user's visualization of three-dimensional images on the display.

A medical visualisation system including a first medical visualisation device having a first device colour identifier, a second medical visualisation device having a second device colour identifier, a third medical visualisation device having a third device colour identifier, and a monitor device, the first device colour identifier being a first colour, the second device colour identifier being a second colour, and the third device colour identifier being a third colour. The first colour has a first hue angle, the second colour has a second hue angle, and the third colour has a third hue angle, wherein the first hue angle and the second hue angle differ by more than 40 degrees, the second hue angle and the third hue angle differ by more than 40 degrees, and the third hue angle and the first hue angle differ by more than 40 degrees.

A point-of-care system with a diagnostic tool and a base station with a display and in communication with the diagnostic tool is described. Used in diagnosing health conditions for a tissue under analysis, the diagnostic tool includes a handle and a head portion. The head portion includes a speculum and optical spectroscopy (OS) data acquisition components positioned within the head portion. The OS data acquisition components are configure to (i) emit light toward the tissue under analysis, (ii) receive light reflected at least in part from the tissue under analysis based on the emitted light, and (iii) determine reflectance spectra associated with the received light. Either the diagnostic tool or a base station includes analytic components configured to (i) generate diagnostic metrics including characteristics of the reflectance spectra and (ii) compare these characteristics to data associated with characteristics of known reflectance spectra associated healthy and/or unhealthy tissue of patients.

An endoscope including a handle including a fulcrum with a fulcrum axis, and a control lever including a lever body attached to the fulcrum and rotatable about the fulcrum axis, a lever grip, and a lever arm attaching the lever grip to the lever body, the control lever being adjustable between a first and a second configuration, in which the gripping surface of the lever grip is distanced from the fulcrum axis at a first radial distance via the lever body and lever arm, and a second configuration, in which the gripping surface of the lever grip is distanced from the fulcrum axis at a second radial distance via the lever body and lever arm, wherein the second radial distance is different from the first radial distance.

Aspects of stone identification methods and systems are described. According to one aspect, an exemplary method comprises: transmitting to a processing unit, with an imaging element mounted on a distal end of a scope, image data about a stone object inside a body cavity; generating from the image data, with the processing unit, a visual representation of the stone object and the body cavity; establishing from a user input, with the processing unit, a scale for the visual representation; determining from the visual representation, with the processing unit, a size of the stone object on the scale; comparing, with the processing unit, the size of the stone object with a predetermined maximum size to determine a removal status; and augmenting, with the processing unit, the visual representation to include an indicator responsive to the removal status. Associated systems are also described.

The present disclosure relates to remote medical examination of a patient, and, more specifically, to a remote exam attachment that, along with a user device, may capture images of an anatomical feature for examination of a patient. The remote exam attachment may include a lens and may couple to an examination tool, such as a speculum, a scope, or a tongue depressor, which may be used with a camera of the user device. The user device may be configured to adjust one or more settings of the camera, such as the zoom, field of view, aperture, and/or the like. The user device may further be configured to transmit an image captured in conjunction with the remote exam attachment to another user device. Accordingly, the remote exam attachment, along with the user device, may capture, display, and/or transmit images of an anatomical feature, facilitating remote examination of a patient.

A method of operating a surgical anchoring system can include inserting an outer sleeve of a surgical instrument at least partially into a first natural body lumen, the outer sleeve having a working channel. The method can include inserting a channel arm of the surgical instrument through the working channel of the outer sleeve and into a second natural body lumen. The channel arm has at least one first anchor member coupled thereto and a control actuator operatively coupled to the at least one first anchor member. The method can include expanding the at least one first anchor member from an unexpanded state to an expanded state to form an anchor point at a portion of the second natural body lumen. The method can include controlling, by the control actuator, a motion of the channel arm to selectively manipulate an organ associated with the first and second natural body lumens.

A magnifying glass captures an image of a tooth by a plurality of cameras for observation. The plurality of cameras includes a narrow range camera capturing a narrow range image of the tooth and a wide range camera capturing a wide range image of the tooth. The magnifying glass includes a three-dimensional position calculator detecting a three-dimensional position of at least the tooth based on the wide range image; a blur correction processor correcting a blur of the narrow range image, based on a change in a three-dimensional positional relationship between the tooth, the three-dimensional position of which has been detected by the three-dimensional position detector, and the narrow range camera; and an image display portion displaying at least the narrow range image having the blur corrected.

A video laryngoscope including a display portion, a handle, and a camera assembly. The display portion includes a housing having a patient-facing side and a user-facing side. A display screen is disposed on the user-facing side and configured to display images captured by the camera assembly. An infrared window is disposed at another position on the video laryngoscope, such as on the patient-facing side of the housing. Infrared signals for pairing the video laryngoscope to other devices, such as monitors or external display screens, may be transmitted through the infrared window. For instance, an infrared receiver of the video laryngoscope may receive infrared signals through the infrared window and/or an infrared transmitter of the video laryngoscope may transmit infrared signals through the infrared window.