Abstract: A system for treating and/or diagnosing tissue from a tissue surface comprises: a console; an interface assembly; and a mobile device. The mobile device is configured to navigate a tissue surface and can comprise: a first tissue attachment assembly; a second tissue attachment assembly; and at least one articulation assembly. The interface assembly operably connects the console to the mobile device. The console is configured to manipulate the at least one articulation assembly via the interface assembly. The at least one articulation assembly is configured to navigate from a first tissue location to a second tissue location. The mobile device is configured to diagnose and/or treat tissue at the second tissue location. Methods of treating and/or diagnosing tissue are also described.

Abstract: Provided in accordance with the present disclosure are systems, methods, and computer readable media for providing guidance for positioning a body and a surgical robot. An exemplary system includes an image capture device configured to capture an image of a surgical training environment and generate image data of the surgical training environment, a head-mounted display, and a computing device configured to receive a surgical training parameter, receive the image data of the surgical training environment, detect a pose of the table and the surgical robot, generate a virtual training environment based on the surgical training environment, determine a pose of a user relative to the surgical training environment, generate guidance for positioning a body on the table or the surgical robot about the body, based on the surgical training parameter and the determined pose of the user, and cause the head-mounted display to display the generated guidance.

Abstract: An endoscope having an outer sheath, a handle, an optical window and an optical module. The outer sheath includes a lumen extending between a proximal end and a distal end thereof. The handle is mounted at the proximal end of the outer sheath and includes an external data connector. The optical window is removably and sealingly mounted at the distal end of the outer sheath. The optical module is removably disposed within the distal end of the outer sheath and includes an integrated image sensor, an optical lens, and an optical module connector. The optical module connector is configured for selective disconnection from and reconnection to a mating line connector in electrical communication with the external data connector of the handle. The optical module and the outer sheath further include one or more alignment features configured to ensure correct radial and axial positioning.

Abstract: Systems for guiding placement of surgical ports on a body include an image capture device configured to capture an image of an operating environment and generate image data based on the captured image, a display device, and a computing device configured to obtain information regarding a location of a surgical site within the body, receive the image data from the image capture device, generate graphical guidance for placing a surgical port on the body based on the location of the surgical site within the body and the image data, and cause the display device to display the generated graphical guidance.

Abstract: An endoscope having an outer sheath, a handle, an optical window, and an optical module. The outer sheath includes a lumen extending between a proximal end and a distal end thereof. The handle is mounted at the proximal end of the outer sheath and includes an external data connector. The optical window is removably and sealingly mounted at the distal end of the outer sheath. The optical module is removably disposed within the distal end of the outer sheath and includes an integrated image sensor, an optical lens, and an optical module connector. The optical module connector is configured for selective disconnection from and reconnection to a mating line connector in electrical communication with the external data connector of the handle. The optical module and the outer sheath further include one or more alignment features configured to ensure correct radial and axial positioning.

Abstract: Systems for guiding placement of surgical ports on a body include an image capture device configured to capture an image of an operating environment and generate image data based on the captured image, a display device, and a computing device configured to obtain information regarding a location of a surgical site within the body, receive the image data from the image capture device, generate graphical guidance for placing a surgical port on the body based on the location of the surgical site within the body and the image data, and cause the display device to display the generated graphical guidance.

Abstract: The present disclosure relates to surgical port assemblies including a plurality of inflatable members for applying a force to a portion of a shaft of a surgical instrument which is inserted through an interior space of the surgical port assembly, and to surgical systems including a surgical port assembly, an endoscopic camera, and a control mechanism for controlling inflation and deflation of the plurality of inflatable members of the surgical port assembly.

Abstract: According to an aspect of the present disclosure, a surgical instrument is provided and includes a housing; an elongate shaft extending from the housing; and a tool assembly supported by a distal portion of the elongate shaft, the tool assembly including first and second jaw member. The at least one of the first and second jaw members is moveable relative to the other jaw member between a neutral configuration in which the first and second jaw members are spaced apart relative to one another; and a clamping configuration in which the first and second jaw members are approximated relative to one another with tissue grasped therebetween, the first jaw member defining a cavity.

Abstract: A surgical robotic system includes a control tower, a mobile cart, and a surgical console. The mobile cart is coupled to the control tower and includes a surgical robotic arm. The surgical robotic arm includes a surgical instrument and an image capture device. The surgical instrument is actuatable in response to a user input and configured to treat a target tissue in real-time. The image capture device for capturing at least one of images or video of the target tissue in real-time. The surgical console includes a user input device for generating a user input, and a controller. The controller is operably coupled to the user input device and configured to switch, based on the user input, from a first mode to a second mode, and from the second mode to the first mode.

Abstract: Systems and methods for compensating for observer movement during robotic surgery. An exemplary system includes an image capture device configured to capture images of a surgical site, a stereoscopic display device, a sensor configured to detect positions of an observer, and a computing device including a processor and a memory storing instructions. The instructions, when executed by the processor, cause the computing device to receive the images of the surgical site from the image capture device, receive data from the sensor indicating a position of the observer, process the received images of the surgical site based on the movement of the observer, and cause the stereoscopic display device to display the processed images of the surgical site.

Abstract: A position and tracking system for radio-based localization in an operating room, includes a receiver, a mobile cart, a processor, and a memory coupled to the processor. The mobile cart includes a robotic arm and a transmitter in operable communication with the receiver. The memory has instructions stored thereon which, when executed by the processor, cause the system to receive, from the transmitter, a signal including a position of the mobile carts in a 3D space based on the signal communicated by the transmitter and determine a spatial pose of the mobile carts based on the received signal.

Abstract: An endoscope having an insertion tube with a distal optical module and a releasable handle. In a semi-robotic embodiment, the handle comprises haptic controllers and a computer configured for steering and/or adjusting physical properties of the insertion tube in response to one or more command inputs from the haptic controllers. The computer may also convert image data received from the optical module into two-dimensional images displayable on a monitor. The endoscope may have inertial measurement units (IMUs) for providing data to the computer for creating a digital three-dimensional image representation of an anatomy model and/or for facilitating handling properties of the endoscope.

Abstract: A method for mapping and fusing endoscopy images includes capturing a first image of an object within a surgical operative site, by a first imaging device; and capturing a second image of the object, by a second imaging device. The first image includes the first light radiating from the object, and a first reference point. The second image includes the second light radiating from the object, and a second reference point. The method further includes comparing a first location of the first reference point in the first image to a second location of the second reference point in the second image, determining a relative pose of the first imaging device to the second imaging device based on the comparing, generating an augmented image fusing the first image and the second image based on the determined relative pose, and displaying the augmented image on a display.

Abstract: A controller includes an attachment member and an interface. The attachment member is configured to secure the controller to a hand of a clinician. The interface includes a first controller that is configured to operate an imaging device of a surgical system. The controller can secure about a finger of a clinician and be engagable by a thumb of the same hand of the clinician. Alternatively, the controller can be disposed in a palm of a hand of a clinician and engaged by a finger of the hand.

Abstract: An endoscope that includes an elongated bougie, a distal tip at a distal end of the bougie and a handle at a proximal end of the bougie. The distal tip has a camera, an LED light, and a distal tip housing forming a distal tip chamber. The endoscope also has an electronic connector, such as a PCB board connector, having at least one PCB board, and at least a portion of the PCB board is nestled within the distal tip chamber. The PCB board connector is disposed between the distal tip and the distal end of the elongated bougie when being assembled. The distal tip and the PCB board connector are attached into one integral distal assembly by removable attaching means, such as a pair of snap fit hood and holder. The integral distal end assembly is configured to be cut from the old bougie used in a medical procedure and to be collected and later disassembled, sterilized, and reassembled with another new bougie.

Abstract: Methods, systems, and computer-readable media for detecting image degradation during a surgical procedure are provided. A method includes receiving images of a surgical instrument; obtaining baseline images of an edge of the surgical instrument; comparing a characteristic of the images of the surgical instrument to a characteristic of the baseline images of the edge of the surgical instrument, the images of the surgical instrument being received subsequent to obtaining the baseline images of the edge of the surgical instrument and being received while the surgical instrument is disposed at a surgical site in a patient; determining whether the images of the surgical instrument are degraded, based on the comparing of the characteristic of the images of the surgical instrument and the characteristic of the baseline images of the surgical instrument; and generating an image degradation notification, in response to a determination that the images of the surgical instrument are degraded.

Abstract: A method for object detection in endoscopy images includes capturing an image of an object, by an imaging device, the image including a first light and a second light. The object includes an infrared (IR) marking. The method further includes accessing the image, performing real time image recognition on the image to detect the IR marking, performing real time image recognition on the image to detect the object and classify the object, based on the IR marking, generating an augmented image based on removing the IR marking from the image, and displaying the augmented image on a display.

Abstract: A surgical robotic system includes: a surgical console having a display and a user input device configured to generate a user input and a surgical robotic arm having a surgical instrument configured to treat tissue and being actuatable in response to the user input; and a video camera configured to capture video data that is displayed on the display. The system also includes a control tower coupled to the surgical console and the surgical robotic arm. The control tower is configured to: process the user input to control the surgical instrument and to record the user input as input data; train a machine learning system using the input data and the video data; and execute the at least one machine learning system to determine probability of failure of the surgical instrument.

Abstract: A surgical robotic system includes a surgical console having a display and a user input device configured to generate a user input and a surgical robotic arm, which includes a surgical instrument configured to treat tissue and being actuatable in response to the user input and a video camera configured to capture video data that is displayed on the display. The system also includes a control tower coupled to the surgical console and the surgical robotic arm. The control tower is configured to process the user input to control the surgical instrument and to record the user input as input data; communicate the input data and the video data to at least one machine learning system configured to generate a surgical process evaluator; and execute the surgical process evaluator to determine whether the surgical instrument is properly positioned relative to the tissue.

Abstract: A tissue suturing guidance system includes an image capturing device, a display, and a processor in communication with the image capturing device and the display. The image capturing device is configured to capture a suture site. The display is configured to display an image of the suture site. The processor is configured to: determine, based on the image of the suture site, a geometric tissue representation of the suture site; access measured properties of the suture site; determine, based on the measured properties of the suture site, a biomechanical tissue representation of the suture site; and generate, based on the geometric tissue representation and biomechanical tissue representation of the suture site, a suturing configuration for the suture site.