Abstract: Robotic and/or surgical devices, systems, and methods include a robotic device. The robotic device includes a manipulator, a drive unit coupled to the manipulator, and a processor coupled with the drive unit. The processor is configured determine that a cannula is mounted to the manipulator and inhibit, using the drive unit, manual articulation of the manipulator in response to determining that the cannula is mounted to the manipulator. In some embodiments, the robotic device further includes a linkage. The processor is further configured to determine a manual effort against the manipulator; inhibit, using the drive unit, the manual articulation of the linkage in response to the manual effort being below an articulation threshold; and facilitate, using the drive unit and in response to not determining that the cannula is mounted to the manipulator, the manual articulation of the linkage in response to the manual effort exceeding the articulation threshold.

Abstract: A method for a minimally invasive surgical system is disclosed including capturing camera images of a surgical site; generating a graphical user interface (GUI) including a first colored border portion in a first side and a second colored border in a second side opposite the first side; and overlaying the GUI onto the captured camera images of the surgical site for display on a display device of a surgeon console. The GUI provides information to a user regarding the first electrosurgical tool and the second tool in the surgical site that is concurrently displayed by the captured camera images. The first colored border portion in the GUI indicates that the first electrosurgical tool is controlled by a first master grip of the surgeon console and the second colored border portion indicates the tool type of the second tool controlled by a second master grip of the surgeon console.

Abstract: Robotic and/or surgical devices, systems, and methods include a manipulator configured to be mounted to a cannula and a processor. The processor is configured to detect a mounting state of the cannula, detect an input indicating the system is to be in a set-up mode, and inhibit transition of the system to the set-up mode in response to the detected mounting state. In some embodiments, detecting the input indicating the system is to be in the set-up mode includes detecting an activation of a dedicated input button. In some embodiments, detecting the input indicating the system is to be in the set-up mode comprises detecting a joint operation of a first kinematic structure coupling the manipulator with a platform that is supported by a second kinematic structure.

Abstract: A patient side cart for a teleoperated surgical system may include a base, a column connected to the base, a boom connected to the column, a manipulator arm connected to the boom, and a vibration reduction member. The manipulator arm may be configured to support a surgical instrument. The vibration reduction member may be configured to be moved between deployed and retracted positions relative to the base. The vibration reduction member may engage a ground surface in the deployed position and not be in contact with the ground surface in the retracted position. Various exemplary embodiments also relate to carts including a vibration reduction member and methods of controlling a vibration reduction member.

Abstract: A system and method of aligning with a reference target includes a computer-assisted medical device. The computer-assisted medical device includes an orientation platform, one or more first joints proximal to the orientation platform, one or more second joints distal to the orientation platform, one or more links distal to the orientation platform, a reference instrument coupled to the orientation platform by the second joints and the links; and a control unit coupled to the first joints and the second joints. The control unit determines a pose of the reference instrument. The pose includes a reference point and a reference orientation. The control unit further positions the orientation platform over the reference point using the first joints, rotates the orientation platform to align the orientation platform with the reference orientation using the first joints, and maintains the pose of the reference instrument using the second joints.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. A set-up mode employs an intuitive user interface in which one or more joints of the kinematic linkage are initially held static by a brake or joint drive system. The user may articulate the joint(s) by manually pushing against the linkage with a force, torque, or the like that exceeds a manual articulation threshold. Articulation of the moving joints is facilitated by modifying the signals transmitted to the brake or drive system. The system may sense completion of the reconfiguration from a velocity of the joint(s) falling below a threshold, optionally for a desired dwell time. Embodiments of the invention can provide for manual movement of a platform supporting a plurality of surgical manipulators or the like without having to add additional input devices.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. One or more kinematic linkage sub-systems may include joints that are actively driven, passive, or a mix of both, and may employ a set-up mode in which one or more of the joints are actively driven in response to manual articulation of one or more other joints of the kinematic chain. In an exemplary embodiment, the actively driven joints will move a platform structure that supports multiple manipulators in response to movement of one of the manipulators, facilitating and expediting the arrangement of the overall system by moving those multiple manipulators as a unit into alignment with the workspace. Manual independent positioning of the manipulator can be provided through passive set-up joint systems supporting the manipulators relative to the platform.

Abstract: A user interface for a surgical system can include a display configured to output video images of a remote surgical site at which one or more electrosurgical instruments of the surgical system are deployed; and a graphical user interface configured to be output on the display with the video images. The graphical user interface may comprise a visual indication of a state of the one or more electrosurgical instruments that indicates a state of the one or more electrosurgical instruments being ready for activation to deliver energy or actively delivering energy.

Abstract: A system for controlling a surgical instrument comprises an input device operably coupled to remotely control movement of a surgical instrument operably coupled to a computer-assisted surgical system; a first auxiliary input device configured to transmit an auxiliary function control signal to activate an auxiliary function of a surgical instrument in an operably coupled state of the first auxiliary input device and the surgical instrument.

Abstract: A teleoperated surgical system may comprise a plurality of teleoperated surgical instruments; a user input device; and a controller operably coupled to the user input device and to the plurality of surgical instruments. The user input device may be configured to transmit an activation command to cause activation of a function of a first one of the plurality of surgical instruments in response to input at the user input device, the function being supported by remote-control supply equipment. The controller may be configured to output a feedback command to cause feedback to a user, the feedback indicating the first one of the plurality of surgical instruments is configured for activation in response to the activation command.

Abstract: A method of assigning an auxiliary input device to control a surgical instrument in a robotic surgical system may include detecting a first surgical instrument coupled to a first manipulator interface assembly of a teleoperated surgical system, the manipulator interface assembly being controlled by a first input device; detecting which one of a user's left and right hands operates the first input device; and assigning control of an auxiliary function of the first surgical instrument to a first auxiliary input device disposed in a left position relative to a second auxiliary input device if the user's left hand is detected to operate the first input device, or assigning control of an auxiliary function of the first surgical instrument to a second auxiliary input device disposed in a right position relative to the first auxiliary input device if the user's right hand is detected to operate the first input device.

Abstract: A teleoperational medical system for performing a medical procedure in a surgical field includes a dynamic guided setup system having step-by-step setup instructions for setting up a teleoperational assembly having at least one motorized surgical arm configured to assist in a surgical procedure. It also includes a user interface configured to communicate the step-by-step setup instructions to a user. The dynamic guided setup system is configured to automatically recognize completion of a first setup step based on detected physical arrangement of at least one surgical arm on a teleoperational assembly and automatically display a prompt for a subsequent setup step after the recognizing completion of the first setup step.

Abstract: A system and method of aligning with a reference target includes a computer-assisted medical device. The computer-assisted medical device includes an orientation platform, one or more first joints proximal to the orientation platform, one or more second joints distal to the orientation platform, one or more links distal to the orientation platform, a reference instrument coupled to the orientation platform by the second joints and the links; and a control unit coupled to the first joints and the second joints. The control unit determines a pose of the reference instrument. The pose includes a reference point and a reference orientation. The control unit further positions the orientation platform over the reference point using the first joints, rotates the orientation platform to align the orientation platform with the reference orientation using the first joints, and maintains the pose of the reference instrument using the second joints.

Abstract: A patient side cart for a teleoperated surgical system may include a base, a column connected to the base, a boom connected to the column, a manipulator arm connected to the boom, and a vibration reduction member. The manipulator arm may be configured to support a surgical instrument. The vibration reduction member may be configured to be moved between deployed and retracted positions relative to the base. The vibration reduction member may engage a ground surface in the deployed position and not be in contact with the ground surface in the retracted position. Various exemplary embodiments also relate to carts including a vibration reduction member and methods of controlling a vibration reduction member.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. One or more kinematic linkage sub-systems may include joints that are actively driven, passive, or a mix of both. A set-up mode employs an intuitive user interface in which one or more joints are initially held static by a brake or joint drive system. The user may articulate the joint(s) by manually pushing against the linkage with a force, torque, or the like that exceeds a manual articulation threshold. Articulation of the moving joints is facilitated by modifying the signals transmitted to the brake or drive system. The system may sense completion of the reconfiguration from a velocity of the joint(s) falling below a threshold, optionally for a desired dwell time. The system may provide a detent-like manual articulation that is not limited to mechanically pre-defined detent joint configurations.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. A set-up mode employs an intuitive user interface in which one or more joints of the kinematic linkage are initially held static by a brake or joint drive system. The user may articulate the joint(s) by manually pushing against the linkage with a force, torque, or the like that exceeds a manual articulation threshold. Articulation of the moving joints is facilitated by modifying the signals transmitted to the brake or drive system. The system may sense completion of the reconfiguration from a velocity of the joint(s) falling below a threshold, optionally for a desired dwell time. Embodiments of the invention can provide for manual movement of a platform supporting a plurality of surgical manipulators or the like without having to add additional input devices.

Abstract: A teleoperated surgical system may comprise a plurality of teleoperated surgical instruments; a user input device; and a controller operably coupled to the user input device and to the plurality of surgical instruments. The user input device may be configured to transmit an activation command to cause activation of a function of a first one of the plurality of surgical instruments in response to input at the user input device, the function being supported by remote-control supply equipment. The controller may be configured to output a feedback command to cause feedback to a user, the feedback indicating the first one of the plurality of surgical instruments is configured for activation in response to the activation command.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. One or more kinematic linkage sub-systems may include joints that are actively driven, passive, or a mix of both. A set-up mode employs an intuitive user interface in which one or more joints are initially held static by a brake or joint drive system. The user may articulate the joint(s) by manually pushing against the linkage with a force, torque, or the like that exceeds a manual articulation threshold. Articulation of the moving joints is facilitated by modifying the signals transmitted to the brake or drive system. The system may sense completion of the reconfiguration from a velocity of the joint(s) falling below a threshold, optionally for a desired dwell time. The system may provide a detent-like manual articulation that is not limited to mechanically pre-defined detent joint configurations.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. One or more kinematic linkage sub-systems may include joints that are actively driven, passive, or a mix of both, and may employ a set-up mode in which one or more of the joints are actively driven in response to manual articulation of one or more other joints of the kinematic chain. In an exemplary embodiment, the actively driven joints will move a platform structure that supports multiple manipulators in response to movement of one of the manipulators, facilitating and expediting the arrangement of the overall system by moving those multiple manipulators as a unit into alignment with the workspace. Manual independent positioning of the manipulator can be provided through passive set-up joint systems supporting the manipulators relative to the platform.