A system and method are provided for planning a tool path for an end-effector of a surgical robot from a first position to a second position using an environmental map. The end-effector may safely and efficiently follow the tool path to re-position the end-effector back to a cutting position following the displacement of the end-effector from the cutting position. Additionally, the environmental map is used to update a virtual representation of a bone to provide a user with visual feedback as to the progression of the end-effector tool as the tool removes material from the bone during a surgical procedure.

An end effector for impacting a prosthesis at a surgical site along a trajectory maintained by a surgical robot. The end effector comprises an impactor assembly and a guide. The impactor assembly has a head to receive impact force, an interface to releasably attach to the prosthesis, a shaft extending along an impactor axis between the head and the interface, and an impactor engagement surface disposed between the head and the interface. The guide is adapted to attach to the surgical robot and comprises a channel extending along a guide axis and defining an opening arranged to receive a portion of the shaft of the impactor assembly, a guide engagement surface shaped to abut the impactor engagement surface, and a limiter to maintain abutment of the impactor engagement surface with the guide engagement surface to facilitate coaxial alignment of the axes with the trajectory maintained by the surgical robot.

A cutting device is provided that includes a pair of cutting blades joined at a pivot point. The cutting blades are driven by an actuator to cause the cutting blades to pivot about the pivot point. The cutting device is configured to remove material underneath a surface of an implant installed on a bone during a revision arthroplasty procedure. The cutting device may travel along a length of the bone just underneath the surface of the implant to remove material and free the implant from the bone. A method for removing material underneath a surface of an implant installed on the bone is also provided. A system for removing material underneath the surface of an implant installed on the bone with the cutting device is also provided.

A surgical robotic system is provided for use in a surgical procedure. The surgical robotic system comprises a surgical arm (080) comprising a movable arm part (082) for mounting of a surgical instrument (119), the movable arm part having at least one degree-of-freedom to enable longitudinal movement (109) of the surgical instrument towards a surgical target (123). A human machine interface (020) is provided for receiving positioning commands (022) from a human operator for controlling the longitudinal movement of the surgical instrument, and an actuator (060) is configured and arranged for actuating the movable arm part to effect the longitudinal movement of the surgical instrument. The actuator is controlled by a processor in accordance with the positioning commands and a virtual bound (132-135). The virtual bound establishes a transition in the control of the longitudinal movement of the surgical instrument in a direction towards the surgical target. The virtual bound is determined, during use of the surgical robotic system, based on the positioning commands.

Advantageously, the human operator is provided with safer and/or more accurate control over the surgical instrument in the vicinity of a surgical target.

A robotic surgical tool includes an elongate shaft extended through a handle and having an end effector arranged at a distal end thereof, a rack extending along a portion of the shaft and operatively coupled to a knife located at the end effector, a first actuation system housed within the handle and operable to drive the rack and thereby advance or retract the knife at the end effector, the first actuation system including a sector gear engageable with the rack and including a tooth-free zone, and a second actuation system housed within the handle and operable to cause z-axis translation of the shaft through the handle. Rotating the sector gear such that the tooth-free zone faces the rack decouples the shaft from the first actuation system to allow the shaft to freely move in z-axis translation.

Certain aspects relate to systems and techniques for an input device for controlling a robotic surgical tool. The input device can include a first pair of opposing links and a second pair of opposing links. The first pair of opposing links and second pair of opposing links can be arranged radially symmetrically. The input device can be configured to control operation of the robotic surgical tool.

A method for a robotic surgical system includes displaying a graphical user interface on a display to a user, wherein the graphical user interface includes a plurality of reconfigurable display panels, receiving a user input at one or more user input devices, wherein the user input indicates a selection of at least one software application relating to the robotic surgical system, and rendering content from the at least one selected software application among the plurality of reconfigurable display panels.

A medical robot system, including a robot coupled to an effectuator element with the robot configured for controlled movement and positioning. The system may include a transmitter configured to emit one or more signals, and the transmitter is coupled to an instrument coupled to the effectuator element. The system may further include a motor assembly coupled to the robot and a plurality of receivers configured to receive the one or more signals emitted by the transmitter. A control unit is coupled to the motor assembly and the plurality of receivers, and the control unit is configured to supply one or more instruction signals to the motor assembly. The instruction signals can be configured to cause the motor assembly to selectively move the effectuator element.

In accordance with one embodiment, an automated probe system includes a probe configured to be reversibly inserted into a live body part, a robotic arm attached to the probe and configured to manipulate the probe, a first sensor configured to track movement of the probe during an insertion and a reinsertion of the probe in the live body part, a second sensor configured to track movement of the live body part, and a controller configured to calculate an insertion path of the probe in the live body part based on the tracked movement of the probe during the insertion, and calculate a reinsertion path of the probe based on the calculated insertion path while compensating for the tracked movement of the live body part, and send control commands to the robotic arm to reinsert the probe in the live body part according to the calculated reinsertion path.

Certain aspects relate to systems and techniques for an input device for controlling a robotic surgical tool. The input device can include a first pair of opposing links and a second pair of opposing links. The first pair of opposing links and second pair of opposing links can be arranged radially symmetrically. The input device can be configured to control operation of the robotic surgical tool.