A system and method of assisting tool exchange includes a computer-assisted device having a manipulator configured to have at least one tool of multiple tools mounted thereon and a control unit coupled to the manipulator. The control unit is configured to detect initiation of a tool exchange, locate a source of a replacement tool to be mounted to the manipulator, determine, based on the located source, a configuration of the manipulator that facilitates mounting of the replacement tool to the manipulator, and command movement of the manipulator into the configuration. In some embodiments, the control unit is configured to determine the configuration further based on a type of the source of the replacement tool. In some embodiments, to locate the source of the replacement tool, the control unit is configured to locate at least a part of an assistant or locate a tool holding device.

A surgical system and method for maintaining optimal surgeon-controlled tissue force or torque with a surgical robot in which a surgical instrument held by an additional robotic arm that is not being actively telemanipulated by a surgeon applies a force or torque to tissue.

Various robotic surgical systems are provided. A robotic surgical system comprises a robotic tool, a control system, and a control module. The control system comprises a control console configured to receive a first user input, and also comprises a control unit in signal communication with the control console and the robotic tool. The control module is configured to receive a second user input, and is in signal communication with the control system.

A method of operating a surgical instrument is disclosed. The surgical instrument includes an electronic system comprising an electric motor coupled to the end effector; a motor controller coupled to the motor; a parameter threshold detection module configured to monitor multiple parameter thresholds; a sensing module configured to sense tissue compression; a processor coupled to the parameter threshold detection module and the motor controller; and a memory coupled to the processor. The memory stores executable instructions that when executed by the processor cause the processor to monitor multiple levels of action thresholds and monitor speed of the motor and increment a drive unit of the motor, sense tissue compression, and provide rate and control feedback to the user of the surgical instrument.

A surgical system is disclosed including a surgical tool, a motor operably coupled to the surgical tool, and a control circuit coupled to the motor. The control circuit is configured to receive an instrument motion control signal indicative of a user input, cause the motor to move the surgical tool in response to the instrument motion control signal, receive an input signal indicative of a distance between the surgical tool and tissue, and scale the movement of the surgical tool to the user input in accordance with the input signal.

The disclosure relates to a dental screwdriver having a shaft portion made of a smart type alloy that bends with little or no resistance along an arch forming portion thereof and without imparting torqueing forces along a distal front end portion thereof onto which is connected a drive tip designed to interface with an appropriately sized screw. The smart alloy automatically assumes its original shape in the absence of twisting forces on the shaft along the arch forming portion. In an alternate embodiment, assuming the original shape involves applying heat and/or subtle finger pressure. The dental screwdriver may be part of a set of screwdrivers, each having a distal front end portion which is uniquely weighted, sized and/or dimensioned to accommodate different driver tips, handle different torqueing functions, and/or configured to bend to a specific maximum angular arch without permanent deformation. A dental prosthetic having a curved bore cavity is also described.

A method for adjusting the operation of a surgical instrument using machine learning in a surgical suite is disclosed. The method comprises the steps of gathering data during surgical procedures, wherein the surgical procedures include the use of a surgical instrument, analyzing the gathered data to determine an appropriate operational adjustment of the surgical instrument, and adjusting the operation of the surgical instrument to improve the operation of the surgical instrument.

A control system of a surgical robotic system, the surgical robotic system comprising a first robot arm and a second robot arm, each of the first and second robot arms comprising a series of joints by which the configuration of that robot arm can be altered, the series of joints extending from a base at a proximal end of the robot arm to an attachment for a surgical instrument at a distal end of the robot arm, the control system being configured to reconfigure the surgical robotic system by: controlling the first robot arm to operate in a surgical mode in which a first surgical instrument attached to that first robot arm is inside a patient's body; and whilst the first robot arm is operating in the surgical mode: (i) controlling the second robot arm so as to permit a second surgical instrument attached to the second robot arm to be inserted into a port in the patient's body; (ii) determining a fulcrum about which the second surgical instrument pivots when the configuration of the second robot arm is altered whilst the second surgical instrument is inside the port; and (iii) controlling the second robot arm to operate in a surgical mode in which the configuration of the second robot arm and second surgical instrument is controlled in response to inputs received at a remote surgeon console whilst maintaining an intersection between the second surgical instrument and the determined fulcrum.

This disclosure covers various concepts to use for obtaining measurement of tension in catheter pullwires to improve controllability of a robotic surgical system.

A controller for controlling the configuration of a joint in a surgical robot, the joint being driven by a drivetrain which transfers power from a drive source to the joint, wherein the controller is configured to: receive a first input indicating a configuration of the drive source; receive a second input from a first sensor, the second input indicating a measured configuration of the joint in the surgical robot; calculate a value of output torque about the joint using the first input and the second input; and calculate, using the value of output torque, a value of input torque to be applied to the joint in the surgical robot by the drive source.