Abstract: Systems and methods for operating an end effector include an end effector for grasping a material, a drive system coupled to the end effector, a user interface, and a processor. The processor is configured to actuate the drive system to clamp the material using the end effector and in response to detecting successful clamping of the material, display a timer on the user interface. The timer provides an indication of when conditions will be safe to proceed with stapling of the material clamped by the end effector.

Abstract: A medical system can include a medical gas duct comprising a first end, a second end opposite the first end, a first opening at the first end of the duct, and a second opening at the second end of the duct. The first opening can be positioned to receive medical gas exiting an exhaust port of a medical gas evacuation unit. On the condition a medical suction supply provides a suction at the second opening of the duct, medical gas exiting the exhaust port of the medical gas evacuation unit flows into the first opening of the duct. Devices, systems, and methods relate to evacuating medical gasses.

Abstract: A system comprises a medical function unit comprising a connector interface configured to be operably coupled to control a medical function of a medical instrument, a control system operably coupled to control the medical function unit, a first user interface and a second user interface each operably coupled to the control system. The first user interface comprises one or more first control settings mapping to one or more corresponding settings of the medical function unit. The second user interface comprises one or more second control settings mapping to the one or more corresponding settings of the medical function. The second user interface is operable during a condition of the first user interface being inoperable.

Abstract: Systems and methods for operating an end effector include an end effector for grasping a material, a drive system coupled to the end effector, and a processor. The processor is configured to use the drive system to grasp a material using the end effector, determine a grasping separation parameter of the end effector, determine, based on the determined grasping separation parameter, a prediction of success or failure in configuring the end effector for firing a staple through the material, and based on the determined grasping separation parameter, output an indicator of whether it is safe to proceed with stapling of the material grasped by the end effector.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: An apparatus may comprise first and second auxiliary function units each one or more connector interfaces configured to be operably connected to one or more medical devices via mating engagement with one or more transmission lines. The apparatus can further include a user interface overlay panel overlying at least a portion of each of the first auxiliary function unit and the second auxiliary function unit. The user interface overlay panel comprises a user interface control portion operably coupled to each of the first auxiliary function unit and second auxiliary function unit to alter control settings of each auxiliary function unit in response to input at the user interface control portion. The user interface control portion further comprises a first and second user interface control areas arranged to align with the one or more connector interfaces of the respective first and second auxiliary function units.

Abstract: A sterile drape assembly may comprise a drape and a cable guide coupled or configured to be coupled to the drape. The drape may comprise a first portion configured to cover a medical device holder and a second portion configured to cover a portion of an arm that supports the medical device holder. The cable guide may comprise two opposing guidepost arms extending in a first direction and defining a first opening and a side arm extending laterally from one of the guidepost arms, the side arm defining a second opening. The first opening is configured to receive and route a first transmission line along a first path. The second opening is spaced from the first opening and is configured to receive and route a second transmission line along a second path spaced from the first path.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: A cannula includes a tube having a central passage extending between a proximal end and a distal end of the tube along a longitudinal axis of the tube. A first cross section of the passage taken at or adjacent the distal end of the tube and in a plane normal to the longitudinal axis has a first cross-sectional shape, the first cross-sectional shape being non-circular. A second cross section of the passage taken through a portion of the tube proximal to the distal end of the tube and in a plane normal to the longitudinal axis has a second cross-sectional shape. The first cross-sectional shape is different from the second cross-sectional shape. Systems related to cannulas and tools for insertion through cannulas.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: Systems and methods for operating an end effector include an end effector for grasping a material, a drive system coupled to the end effector, and a processor. The processor is configured to use the drive system to grasp a material using the end effector, determine a grasping separation parameter of the end effector, determine, based on the determined grasping separation parameter, a prediction of success or failure in configuring the end effector for firing a staple through the material, and based on the determined grasping separation parameter, output an indicator of whether it is safe to proceed with stapling of the material grasped by the end effector.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: Systems and methods for operating an end effector include a first jaw, a second jaw, a first actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a first force, and a second actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a second force greater than the first force. The second actuation mechanism is different from the first actuation mechanism. In some embodiments, the first actuation mechanism includes a first pull cable configured to increase an angle between the first jaw and the second jaw and a second pull cable configured to decrease the angle between the first jaw and the second jaw. In some embodiments, the second actuation mechanism includes a lead screw.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: A patient side cart for a teleoperated surgical system can include at least one manipulator arm portion for holding a surgical instrument, a steering interface, and a drive system. The steering interface may be configured to detect a force applied by a user to the steering interface indicating a desired movement for the teleoperated surgical system. The drive system can include at least one driven wheel, a control module, and a model section. The control module may receive as input a signal from the steering interface corresponding to the force applied by the user to the steering interface. The control module may be configured to output a desired movement signal corresponding to the signal received from the steering interface. The model section can include a model of movement behavior of the patient side cart, the model section outputting a movement command output to drive the driven wheel.

Abstract: Systems and methods for operating an end effector include a first jaw, a second jaw, a first actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a first force, and a second actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a second force greater than the first force. The second actuation mechanism is different from the first actuation mechanism. In some embodiments, the first actuation mechanism includes a first pull cable configured to increase an angle between the first jaw and the second jaw and a second pull cable configured to decrease the angle between the first jaw and the second jaw. In some embodiments, the second actuation mechanism includes a lead screw.

Abstract: A patient side cart for a teleoperated surgical system can include at least one manipulator arm portion for holding a surgical instrument, a steering interface, and a drive system. The steering interface may be configured to detect a force applied by a user to the steering interface indicating a desired movement for the teleoperated surgical system. The drive system can include at least one driven wheel, a control module, and a model section. The control module may receive as input a signal from the steering interface corresponding to the force applied by the user to the steering interface. The control module may be configured to output a desired movement signal corresponding to the signal received from the steering interface. The model section can include a model of movement behavior of the patient side cart, the model section outputting a movement command output to drive the driven wheel.