Abstract: A system comprises a teleoperational assembly including an operator control system and a first teleoperational manipulator configured for operation by an operator control device of the operator control system. The first teleoperational manipulator is configured to control the operation of a first medical instrument in a surgical environment. The system also comprises a processing unit including one or more processors. The processing unit is configured to display an image of a field of view of the surgical environment and display a menu proximate to an image of the first medical instrument in the image of the field of view. The menu includes at least one icon representing a function for the first medical instrument.

Abstract: A teleoperational medical system comprises a teleoperational assembly including an operator control system, a first teleoperational manipulator, a first medical instrument, and a processing unit including one or more processors. The first teleoperational manipulators is configured for operation by an operator control device of the operator control system. The first teleoperational manipulator is configured to control the operation of the first medical instrument in a surgical environment. The processing unit is configured to display an image of a field of view of the surgical environment and display a menu proximate to an image of the first medical instrument in the image of the field of view. The menu includes at least one state indicator representing a state of a component of the first medical instrument.

Abstract: Systems and methods for remotely controlling a system using video are provided. A method in accordance the present disclosure includes detecting a video signal of an auxiliary system at a video input, wherein the video signal including images encoded with control information. The method also includes determining that the images included in the video signal include the control information. The method further includes extracting the control information from the images. Additionally, the method includes modifying operations of the system based on the control information.

Abstract: A medical system may comprise a display system and a processor. The processor may be configured to generate a computer model of a plurality of instruments. The plurality of instruments may extend through and out of a distal end of an entry guide and may include an image capturing instrument. The processor may be further configured to cause an image of the computer model to be displayed on the display system and determine from a configuration of the plurality of instruments in the computer model if an event alert threshold associated with an event has been reached. If a determination is made that the event alert threshold has been reached, an event indicator may be displayed on the display system at a portion of the image of the computer model associated with the event.

Abstract: A computer-assisted medical device is configured and used to endoluminally navigate to a location in the gastrointestinal system and there treat certain body lumen wall areas while avoiding other body lumen wall areas. Embodiments ablate the inner mucosal layer and sub-mucosal nerve plexus of the stomach, duodenum and jejunum to effect treatment of insulin resistance and metabolic disorders, such as Type II diabetes (T2D), polycystic ovarian syndrome (PCOS), non-alcoholic steatohepatitis (NASH), non-alcoholic fatty liver disease (NAFLD), congestive heart failure (CHF) and obstructive sleep apnea (OSA). Various sensors are used to assist a clinical operator to navigate from the mouth through the pyloric sphincter and into and through the duodenum and/or jejunum. Various sensors are used to map and identify portions of the duodenum and/or jejunum. Various lumen wall ablation devices and methods are described. Various post-treatment assessments are described.

Abstract: A medical system may comprise a display and a processor configured to determine an optimal position for an image capturing instrument to view working ends of a plurality of medical instruments when the plurality of medical instruments and the image capturing instrument are each extending out of a distal end of an entry guide. The processor may also be configured to cause the optimal position to be displayed on the display along with an image captured by the image capturing instrument of the working ends of the plurality of medical instruments.

Abstract: A computer-assisted medical device is configured and used to endoluminally navigate to a location in the gastrointestinal system and there treat certain body lumen wall areas while avoiding other body lumen wall areas. Embodiments ablate the inner mucosal layer and sub-mucosal nerve plexus of the stomach, duodenum and jejunum to effect treatment of insulin resistance and metabolic disorders, such as Type II diabetes (T2D), polycystic ovarian syndrome (PCOS), non-alcoholic steatohepatitis (NASH), non-alcoholic fatty liver disease (NAFLD), congestive heart failure (CHF) and obstructive sleep apnea (OSA). Various sensors are used to assist a clinical operator to navigate from the mouth through the pyloric sphincter and into and through the duodenum and/or jejunum. Various sensors are used to map and identify portions of the duodenum and/or jejunum. Various lumen wall ablation devices and methods are described. Various post-treatment assessments are described.

Abstract: A system comprises a teleoperational manipulator configured to control operation of a medical instrument in a surgical environment. The system further comprises an operator input system including an input device and a processing unit including one or more processors. The processing unit is configured to display an image of a field of view of the surgical environment and display a menu including a set of directionally arranged menu options. The processing unit is further configured to transition the input device from a first constraint state for interaction with the medical instrument to a second constraint state for interaction with the menu. In the second constraint state, the input device is constrained to move in one or more directions based on the set of directionally arranged menu options.

Abstract: A medical system comprises an entry guide, a display, and a processor. The processor may be configured to receive state information for an articulatable image capture device controllably extendable out of a distal end of the entry guide. The processor may be configured to generate a view including a graphical representation of a distal end portion of the articulatable image capture device as determined from the received state information and a graphical representation of a field of view of the articulatable image capture device extending distally from the distal end portion of the articulatable image capture device. The processor may also cause the view to be displayed on the display.

Abstract: A system comprises a teleoperational assembly including an operator control system and a first teleoperational manipulator configured for operation by an operator control device of the operator control system. The first teleoperational manipulator is configured to control the operation of a first medical instrument in a surgical environment. The system also comprises a processing unit including one or more processors. The processing unit is configured to display an image of a field of view of the surgical environment and display a menu proximate to an image of the first medical instrument in the image of the field of view. The menu includes at least one icon representing a function for the first medical instrument.

Abstract: A medical robotic system includes an entry guide with surgical tools and a camera extending out of its distal end. To supplement the view provided by an image captured by the camera, an auxiliary view including articulatable arms of the surgical tools and/or camera is generated from sensed or otherwise determined information about their positions and orientations are displayed along with indications of range of motion limitations on a display screen from the perspective of a specified viewing point.

Abstract: A method comprises displaying an image of a field of view of a surgical environment. A first medical instrument in the field of view may be coupled to a first manipulator in a teleoperational assembly. The method may comprise displaying a menu proximate to an image of the first medical instrument in the image of the field of view. The menu may include a plurality of icons wherein each icon is associated with a function for the first medical instrument. The method may also comprise identifying a selected icon from the plurality of icons based upon a movement of an operator control device of a teleoperational operator control system.

Abstract: A method comprises displaying an image of a field of view of a surgical environment. A first medical instrument in the field of view may be coupled to a first manipulator in a teleoperational assembly. The method may comprise displaying a menu proximate to an image of the first medical instrument in the image of the field of view. The menu may include a plurality of icons wherein each icon is associated with a function for the first medical instrument. The method may also comprise identifying a selected icon from the plurality of icons based upon a movement of an operator control device of a teleoperational operator control system.

Abstract: Systems and methods for remotely controlling a system using video are provided. A method in accordance the present disclosure includes detecting a video signal of an auxiliary system at a video input, wherein the video signal including images encoded with control information. The method also includes determining that the images included in the video signal include the control information. The method further includes extracting the control information from the images. Additionally, the method includes modifying operations of the system based on the control information.

Abstract: A robotic system has a plurality of user selectable operating modes. To select one of the operating modes, a user performs a distinguishing action which uniquely identifies a desired operating mode among the plurality of user selectable operating modes. A method implemented by a processor in the robotic system identifies the distinguishing action and places the robotic system in the user selected operating mode.

Abstract: A system comprises a teleoperational assembly including an operator control system and a first teleoperational manipulator configured for operation by an operator control device of the operator control system. The first teleoperational manipulator is configured to control the operation of a first medical instrument in a surgical environment. The system also comprises a processing unit including one or more processors. The processing unit is configured to display an image of a field of view of the surgical environment and display a menu proximate to an image of the first medical instrument in the image of the field of view. The menu includes at least one icon representing a function for the first medical instrument.

Abstract: To perform a tool exchange in a medical robotic system, tool is retracted back into an entry guide from a deployed position and pose so that an assistant in the operating room may replace it with a different tool. While the tool is being retracted back towards the entry guide by user action, its configuration is changed to an entry pose while avoiding collisions with other objects so that it may fit in the entry guide. After the tool exchange is completed, a new tool is inserted in the entry guide and extended out of the guide by user action to the original position of the old tool prior to its retraction into the entry guide while the tool's controller assists the user by reconfiguring the new tool so as to resemble the original deployed pose of the old tool prior to its retraction into the entry guide.

Abstract: A teleoperational system in a surgical environment comprises a teleoperational assembly including a first teleoperational arm, a first display device coupled to the teleoperational assembly, and a processor. The processor is configured to monitor a location of the first display device in the surgical environment and render a first image on the on the first display device. The first image is rendered based upon the location of the first display device in the surgical environment.

Abstract: A robotic system has a plurality of user selectable operating modes. To select one of the operating modes, a user performs a distinguishing action which uniquely identifies a desired operating mode among the plurality of user selectable operating modes. A method implemented by a processor in the robotic system identifies the distinguishing action and places the robotic system in the user selected operating mode.

Abstract: A robotic system has a plurality of user selectable operating modes. To select one of the operating modes, a user performs a distinguishing action which uniquely identifies a desired operating mode among the plurality of user selectable operating modes. A method implemented by a processor in the robotic system identifies the distinguishing action and places the robotic system in the user selected operating mode.