A system is disclosed that includes an optical tracking device and a surgical computing device. The optical tracking device includes a structured light module and an optical module that includes an image sensor and is spaced from the structured light module at a known distance. The surgical computing device includes a display device, a non-transitory computer readable medium including instructions, and processor(s) configured to execute the instructions to generate a depth map from a first image captured by the image sensor during projection of a pattern into a surgical environment by the structured light module. The pattern is projected in a near-infrared (NIR) spectrum. The processor(s) are further configured to execute the stored instructions to reconstruct a 3D surface of anatomical structure(s) based on the generated depth map. Additionally, the processor(s) are configured to execute the stored instructions to output the reconstructed 3D surface to the display device.

A surgical image capture and display system includes a handheld image capture and pointing device and a display assembly. An image is captured by an image sensor of the handheld device and displayed on the display assembly. The image sensor detects light emitted by one or more beacons of the display assembly. The system determines, based on the light emitted by the one or more beacons, a position or orientation of the handheld device relative to the display assembly. The system updates display of a graphical user interface comprising the image on the display assembly in accordance with the determined position or orientation of the handheld device.

A supply tray for a surgical procedure is selected based on the surgical procedure and patient data retrieved from an electronic health records database. Multiple steps of the surgical procedure are retrieved from the electronic health records database. A message is sent to a first manipulator to move a supply from the supply tray to a staging area for performing a step. A first indication is received from a first sensor that the supply is needed at a present time. A position where the supply is needed in an operating area proximate to the staging area is determined using a second sensor. A second message is sent to a second manipulator to move the supply from the staging area to the position. A second indication is received from a third sensor that the step is complete. A third message is sent to a third manipulator to remove the supply.

A method comprises grasping material between a pair of jaw members of a medical instrument; sensing light transmitted from the material grasped between the pair of jaw members to a location exterior to the pair of jaw members; and altering a grasping force exerted by the pair of jaw members on the material being grasped based on the sensing of the light transmitted.

A surgical tool harvests power from a robotic surgical system having one or more robotic manipulators when a housing of the surgical tool is installed within a carriage of one of the robotic manipulators. The surgical tool harvests power via inductive coupling between an inductor of the surgical tool and a corresponding inductor of the carriage. The surgical tool may include an indicator that provides a user with an indication of remaining life of the surgical tool. The indicator may be an LED indicator that is illuminated with power generated via the inductive coupling. The indicator may also be an electro-chromic indicator that changes color when exposed to power generated via the inductive coupling. The indicator may also be a photo-chromic indicator that changes color when exposed to light from a light source powered via the inductive coupling.

A system and method for displaying an endoscope image in a preferred orientation. An endoscope scans a sample with spectrally encoded light by rotating imaging optics inside an endoscope guide. A processor generates an image based on light returned from the sample, and rotates the image by a first angle offset value and a second angle offset value to display the rotated image in the preferred orientation. The first offset value is an angle difference between a specific direction in which the image is to be displayed on a display and a direction in which the tip of the endoscope is oriented with respect to the imaging plane. The second offset value is an angle difference between a direction of the line of scanning light projected onto a plane perpendicular to the tip and the specific direction in which the image is to be displayed.

A medical support arm includes: a support arm that supports an endoscope; an actuator that drives the support arm; a measurement unit that measures a load applied to the actuator; a generation unit that generates three-dimensional information in a body into which the endoscope is inserted; and a correction unit that corrects the three-dimensional information on a basis of the measured load.

Provided herein are platforms and methods for mapping a three-dimensional (3D) dental anatomy of a subject.

An endoscope device includes: a light source capable of switching an optical spectrum of illumination light; an imaging device configured to acquire an image by receiving reflection light of the illumination light; an image processor configured to determine whether or not visibility deterioration has occurred within a visual field of the image acquisition section due to a fragment of a calculus crushed by being irradiated with a laser beam from a laser pulse generator; and a controller configured to control the light source based on a determination result obtained by the image processor. The controller causes the light source to emit white light as the illumination light in response to the image processor determining that the visibility deterioration has not occurred, and switches the illumination light emitted from the light source to light in a blue region in response to the image processor determining that the visibility deterioration has occurred.

Devices, systems, and methods described herein relate to affecting an internal diameter of a body lumen, and, in many examples, of a pylorus. A silk-based bulking agent may be injected in a pyloric tissue so as to reduce an effective inner diameter of the pylorus. A multi-part occluding agent may be injected into a pylorus on the surface of the pyloric tissue to occlude the pylorus alone or in combination with the silk-based bulking agent.