Abstract: A tension compensation system for a robotically controlled medical device can include an instrument controller configured to operatively connect to a robotically controlled medical device to provide tension to one or more actuation cables of the robotically controlled medical device. The system can include an instrument control module configured to control the instrument controller to provide a compensation tension to at least one actuation cable of the one or more actuation cables to compensate for elongation of the at least one actuation cable of the one or more actuation cables based on actuation data associated with the at least one actuation cable of the one or more actuation cables.

Abstract: An end effector for a minimally invasive medical device can include a base configured to attach to a distal end of a shaft, and a disposable distal portion configured to removably attach to the base to be disposed of after use.

Abstract: A force transmission system for a robotically controlled medical device includes a pushing actuator adapted and configured to be pushed distally by a robotic instrument controller, a pivot, and a reverse linkage rotatable about the pivot. The reverse linkage includes a first portion extending between the pivot and the pushing actuator, and operably engaged with the pushing actuator, a second portion extending from the pivot away from the first portion, adapted to engage a control wire of the robotically controlled medical device and pull the control wire proximally in response to distal movement of the pushing actuator, and a distal surface of the second portion having an arcuate surface adapted maintain an axial position of the control wire throughout a range of motion thereof.

Abstract: A user input device for a patient console of a robotic surgical system includes a user-selectable control for each of a plurality of motion devices of the patient console, the plurality of motion devices including a vertical lift device configured to provide up and down motion along a vertical axis, a pitch rotation device configured to provide a pitch rotation about a pitch axis orthogonal to the vertical axis, a translation device configured to provide sliding translation along a translation axis, and a roll rotation device to rotate about a roll axis to provide a roll to an instrument controller assembly.

Abstract: An end effector for a minimally invasive medical device can include a base configured to attach to a distal end of a shaft, and a disposable distal portion configured to removably attach to the base to be disposed of after use.

Abstract: A force transmission system for a robotically controlled medical device can include a pushing actuator configured to be pushed by a robotic instrument controller and a wire. The wire can include a first end attached to an end of the pushing actuator to be pushed distally by the pushing actuator, and a second end attached to a distal location of the medical device. The system can include a reverse motion device that can be interfaced with the wire between the first end and the second end. The reverse motion device can be configured to cause a proximal pulling action on the second end in response to pushing of the first end distally by the pushing actuator or other actuation by the pushing actuator. The reverse motion device can be configured to maintain a point of contact with the wire in the same spatial location to prevent wire motion due to actuation.

Abstract: A patient cart for a robot surgical system can include a mobile base having a frame adapted and configured to support a medical robot, one or more motive devices operatively connected to the frame, and one or more motors connected to the motive devices to drive the motive devices to move the frame. The patient cart can include a drive control interface connected to the frame and configured to sense a user input and to operate the one or more motors to move the one or more motive devices as a function of the user input.

Abstract: A patient console for a robotic surgical system can include a base, a vertical lift attached to a top of the base and configured to provide up and down motion in a vertical axis, a yaw rotation device attached to the top of the vertical lift and configured to provide a yaw rotation about the vertical axis, a pitch rotation device attached to the top of the yaw rotation device and configured to provide a pitch rotation about a pitch axis orthogonal to the vertical axis, a translation device attached to the top of the pitch rotation device and configured to provide sliding translation along a translation axis, and a roll rotation device attached to the translation device to roll relative to the translation device about a roll axis to provide a roll to an instrument controller assembly. An angle of the translation axis and the roll axis relative to horizontal can be a function of the pitch rotation provided by the pitch rotation device.

Abstract: A patient cart for a robot surgical system can include a mobile base having a frame adapted and configured to support a medical robot, one or more motive devices operatively connected to the frame, and one or more motors connected to the motive devices to drive the motive devices to move the frame. The patient cart can include a drive control interface connected to the frame and configured to sense a user input and to operate the one or more motors to move the one or more motive devices as a function of the user input.

Abstract: A steerable overtube assembly for a robotic surgical system can include a steerable shaft having one or more instrument channel and a control hub configured to mount to the steerable shaft. The assembly can also include a manual actuator extending from the control hub and configured to allow the steerable shaft to be manually steered by a user's hand, and a robotic actuator housed by and/or extending from the control hub configured to connect to a robotic driver to allow robotic steering of the steerable shaft.

Abstract: Provided herein is a mechanism to controllably move a wire within a flexible tubular member, the wire including opposed wire ends extending outwardly of a proximal end of the flexible tubular member, comprising a drive mechanism and a coupling located between the drive mechanism and the wire end, wherein movement of the coupling in the direction of the wire end results in opposed motion of the wire end.

Abstract: A steerable overtube assembly for a robotic surgical system can include a steerable shaft having one or more instrument channel and a control hub configured to mount to the steerable shaft. The assembly can also include a manual actuator extending from the control hub and configured to allow the steerable shaft to be manually steered by a user's hand, and a robotic actuator housed by and/or extending from the control hub configured to connect to a robotic driver to allow robotic steering of the steerable shaft.

Abstract: A controller adapter system for a robotic surgical instrument controller assembly can include an instrument controller having a housing and one or more controller actuators. The housing can be configured to receive a drape opening structure on the housing. The system can include an inner drape adapter configured to mount to the instrument controller and extend distally from the instrument controller. The inner drape adapter can include one or more adapter actuators configured to receive actuation from the one or more controller actuators at a proximal side thereof, and to transmit the actuation to a distal side thereof. The system can include an outer drape adapter configured to axially retain the inner drape adapter to the instrument controller. The outer drape adapter can be configured to sandwich the drape opening structure to the housing of the instrument controller.

Abstract: A patient console for a robotic surgical system can include a base, and a positioning assembly attached to the base and configured to position an instrument controller assembly. The positioning assembly includes a remote control device operatively connected to the positioning assembly to control movement of one or more portions of the positioning assembly such that a user is capable of having a direct line-of-sight of a patient when using the remote control device.

Abstract: A method can include inserting a first device into a body lumen having a bend, sliding a first sheath having a first sheath diameter over first device, sliding a second sheath having a second sheath diameter larger than the first sheath diameter over the first device, and navigating the first device through and beyond the bend. The method can also include at least partially straightening the first device to at least partially straighten the bend, removing the first device and the first sheath from the body lumen, leaving the second sheath in place within the at least partially straightened bend, and introducing a second device into the second sheath to navigate the second device through the at least partially straightened bend to an opening of the second sheath.

Abstract: A patient cart for a robot surgical system can include a mobile base having a frame adapted and configured to support a medical robot, one or more motive devices operatively connected to the frame, and one or more motors connected to the motive devices to drive the motive devices to move the frame. The patient cart can include a drive control interface connected to the frame and configured to sense a user input and to operate the one or more motors to move the one or more motive devices as a function of the user input.

Abstract: A patient console for a robotic surgical system can include a base, a vertical lift attached to a top of the base and configured to provide up and down motion in a vertical axis, a yaw rotation device attached to the top of the vertical lift and configured to provide a yaw rotation about the vertical axis, a pitch rotation device attached to the top of the yaw rotation device and configured to provide a pitch rotation about a pitch axis orthogonal to the vertical axis, a translation device attached to the top of the pitch rotation device and configured to provide sliding translation along a translation axis, and a roll rotation device attached to the translation device to roll relative to the translation device about a roll axis to provide a roll to an instrument controller assembly. An angle of the translation axis and the roll axis relative to horizontal can be a function of the pitch rotation provided by the pitch rotation device.

Abstract: A tension compensation system for a robotically controlled medical device can include an instrument controller configured to operatively connect to a robotically controlled medical device to provide tension to one or more actuation cables of the robotically controlled medical device. The system can include an instrument control module configured to control the instrument controller to provide a compensation tension to at least one actuation cable of the one or more actuation cables to compensate for elongation of the at least one actuation cable of the one or more actuation cables based on actuation data associated with the at least one actuation cable of the one or more actuation cables.

Abstract: A force transmission system for a robotically controlled medical device can include a pushing actuator configured to be pushed by a robotic instrument controller and a wire. The wire can include a first end attached to an end of the pushing actuator to be pushed distally by the pushing actuator, and a second end attached to a distal location of the medical device. The system can include a reverse motion device that can be interfaced with the wire between the first end and the second end. The reverse motion device can be configured to cause a proximal pulling action on the second end in response to pushing of the first end distally by the pushing actuator or other actuation by the pushing actuator. The reverse motion device can be configured to maintain a point of contact with the wire in the same spatial location to prevent wire motion due to actuation.

Abstract: An end effector for a minimally invasive medical device can include a base configured to attach to a distal end of a shaft, and a disposable distal portion configured to removably attach to the base to be disposed of after use.