A method includes receiving a torque limit for a motor, monitoring a torque output of the motor, determining an amplitude and a phase of a torque ripple of the torque output, and determining a compensated torque limit for the motor, the compensated torque limit including a first component at the torque limit and a second component at an adjusted torque limit.

A robotic surgical system employs a surgical instrument (20), a robot (40) for navigating the surgical instrument (20) relative to an anatomical region (10) within a coordinate system (42) of the robot (40), and a robot controller (43) for defining a remote center of motion for a spherical rotation of the surgical instrument (20) within the coordinate system (42) of the robot (40) based on a physical location within the coordinate system (42) of the robot (40) of a port (12) into the anatomical region (10). The definition of the remote center of rotation is used by the robot controller (43) to command the robot (40) to align the remote center of motion of the surgical instrument (20) with the port (12) into the anatomical region (10) for spherically rotating the surgical instrument (20) relative to the port (12) into the anatomical region (10).

A histotripsy therapy system configured for the treatment of tissue is provided, which may include any number of features. Provided herein are systems and methods that provide efficacious non-invasive and minimally invasive therapeutic, diagnostic and research procedures. In particular, provided herein are optimized systems and methods that provide targeted, efficacious histotripsy in a variety of different regions and under a variety of different conditions without causing undesired tissue damage to intervening/non-target tissues or structures.

Systems and methods are disclosed for controlling a surgical visualization system using a hands-free (e.g., mouth, nose. and breath actuated) controller. An example system includes a microscope camera associated with the surgical system; a controller of the microscope camera; a processor; and a memory storing instructions for the processor. The controller may be separate from the microscope camera, and may comprise one or more joysticks. In some aspects, the controller may further include a pressure detector configured to detect pressure within a tube of a joystick. Also or alternatively, the controller may include a keyed proximity sensor to activate the controller when a surgeon is present. The processor may be configured to: receive a movement input based on a movement of the joystick along a Cartesian direction; and cause a corresponding movement of the microscope camera along the Cartesian direction.

An adjustable bone fixation device for moving a bone includes at least two strut units, at least one meter and a system controller. Each strut unit includes a motor to move a strut. The meter measures a signal generated by the motor during the movement of its strut. The signal is useful in determining a torque or a current of the motor. The system controller activates at least two of the motors and uses the determined torque or the determined current to identify if there is a clinical situation of the bone or a system issue and provides an alert accordingly.

This application relates to a surgical robot apparatus and a method of driving the surgical robot apparatus. The surgical robot apparatus may include a passive arm, of which a position is set before performing surgery, and an active arm connected to the passive arm, and driven to manipulate a surgical tool while performing surgery. The apparatus may also include a cannula holder which is installed at an end portion of the active arm and in which a cannula for holding the surgical tool is inserted. The apparatus may further include a sensor unit installed between the cannula holder and the end portion of the active arm, and sensing a force and torque applied to the cannula holder and a controller connected to the sensor unit and receiving data about the force and torque.

Described within are systems, methods and apparatus for a bone mounted robotic-assisted orthopedic surgery system for precise implant position, soft tissue balancing and guidance of tools during a surgical procedure, particularly partial or total knee replacement procedure. The system features a bone mounted robotic arm with end-effector for precise positioning of surgical tool, position in of implants and balancing of soft tissues. The reconfigurable robotic system requires minimal training by surgeons, is intuitive to use similar to conventional instrumented surgery and has a small footprint. The system works with existing, conventional instruments, patient specific instruments, sensor-assisted systems and computer-assisted systems and does not require increased surgical time and safely provides the enhanced precision achievable by robotic-assisted systems and computer-assisted technologies.

A generator, ultrasonic device, and method for controlling a temperature of an ultrasonic blade are disclosed. A control circuit coupled to a memory determines an actual resonant frequency of an ultrasonic electromechanical system comprising an ultrasonic transducer coupled to an ultrasonic blade by an ultrasonic waveguide. The actual resonant frequency is correlated to an actual temperature of the ultrasonic blade. The control circuit retrieves from the memory a reference resonant frequency of the ultrasonic electromechanical system. The reference resonant frequency is correlated to a reference temperature of the ultrasonic blade. The control circuit then infers the temperature of the ultrasonic blade based on the difference between the actual resonant frequency and the reference resonant frequency. The control circuit controls the temperature of the ultrasonic blade based on the inferred temperature.

A manipulator system, has an elongated portion having a bending portion and a wire configured to bend the bending portion; an operation portion configured to generate a first force for pulling the wire by an operator; a motor configured to generate a second force for pulling the wire; a clutch mechanism configured to switch a pulling force to pull the wire between to at least one of the first force or the second force; a grasping-state detector configured to determine a grasping state of the operation portion by the operator; and a controller configured to control the motor and the clutch mechanism, wherein the controller is configured to obtain the grasping state from the grasping-state detector, generate a control signal for controlling the clutch mechanism according to the obtained grasping state, and transmit the control signal to the clutch mechanism.

Embodiments provide a method and device for plate osteosynthesis of a bone fracture that allows angle-stable fixation of the bone fracture, while permitting elastic axial motion at the fracture site in a controlled, symmetric manner to stimulate fracture healing. Embodiments pertain to a bone plate having an outer surface and a bone-facing surface. The bone plate incorporating internal sliding elements containing a threaded receiving hole for bone screws that have a correspondingly threaded screw head. The sliding elements undergo controlled displacement parallel to the longitudinal axis of the plate but are substantially constrained against displacement perpendicular to the longitudinal axis of the plate. The bone screws with threaded heads may be rigidly fixed to the threaded receiving holes in the sliding elements without compressing the bone plate onto the hone surface. Sliding elements are elastically suspended inside the bone plate and undergo dynamic motion.