A method includes obtaining rotational data and translational data for a joint. The rotational and translational data is indicative of rotational and translational movement of the joint during rotational and translational joint testing, respectively. The rotational and translational joint testing is implemented by a robotic testing apparatus. Respective zero torque points are determined for the rotational and translational movement based on the rotational data and the translational data. The respective zero torque points are combined for the rotational and translational movement to determine an equilibrium position for the joint. A biomechanical characteristic of the joint is ascertained based on an analysis of the equilibrium position.

The present disclosure relates to delivery systems for delivering and deploying interventional devices to a targeted area within a body, such as delivering a replacement heart valve to a targeted heart valve. A delivery device includes a steerable catheter and a replacement valve delivery system positioned within the steerable catheter and configured to be translatable within the steerable catheter. The steerable catheter includes one or more control wires running from a distal end of the catheter to a handle at the proximal end of the catheter. Each control wire is coupled to a control of the handle such that manipulation of the control provides deflection and control of the steerable catheter.

Provision of a technology capable of realizing estimation of forces of various types of disturbance acting on a robot arm in a surgical environment is desirable. Provided is a medical support arm system including a joint state acquisition unit configured to acquire a state of a joint unit of an arm unit, and an external force estimation unit configured to estimate an external force due to predetermined disturbance on the basis of a condition that the external force due to the predetermined disturbance is limited to one predetermined direction or a plurality of predetermined directions, and a state of the joint unit.

A robotic surgical system configured for the articulation of a catheter includes an input device, a control computer, and an instrument driver having at least one motor for displacing the pull-wire of a steerable catheter wherein the control computer is configured to determine the desired motor torque or tension of the pull-wire of a catheter based on user manipulation of the input device. The control computer is configured to output the desired motor torque or tension of the pull-wire to the instrument driver, whereby at least one motor of the instrument driver implements the desired motor torque to cause the desired pull-wire tension to articulate the distal tip of the catheter.

A power-driven surgical tool that includes an elongated housing having a fin member aligned substantially parallel with the longitudinal axis of such elongated housing. The tool is power-driven and enables the attachment of either a drill bit or a screwdriver bit. The configuration is such as to provide maximum comfort and a visualization of the target area for the surgeon.

A surgical stapler includes a handle assembly, an end effector, a firing rod disposed in mechanical cooperation with the end effector, a drive motor coupled to the firing rod, a sensor, and a controller. The end effector includes a first and second jaw member moveable relative to one another. The first jaw member includes a surgical fastener and the second jaw member includes an anvil. The drive motor is configured to advance the firing rod to cause the first and second jaw members to clamp tissue and to eject a surgical fastener. The surgical stapler includes a sensor that is configured measure a clamping force exerted on tissue by the first and second jaw members. The controller control a speed of the drive motor based on the measured clamping force.

An instrument system includes an instrument, a drive system, and a controller operably connected to a first drive mechanism and a second drive mechanism of the drive system. The controller is configured to operate the first drive mechanism and the second drive mechanism drive a flexible tensioning member of the instrument to cause movement of an end effector of the instrument while maintaining a tension applied to the flexible tensioning member of the instrument in a tension range.

Methods and devices are provided for performing robotic surgery. In general, a surgical system is provided including an electromechanical tool with a first mode of operation in which the electromechanical tool mimics movement of a controller, and a second mode of operation in which the tool mirrors movement of the controller. A hybrid surgical device is also provided including an adapter matable to a handle assembly such that the adapter is electronically coupled to a motor of the handle assembly and is configured to communicate with the motor. A robotic laparoscopic surgical device is also provided including a motion sensor configured to sense movement of an electromechanical tool and an electromechanical arm that assists movement of the tool. A robotic surgical device is also provided including an electromechanical driver associated with a trocar and being configured to rotate and to translate a tool disposed through a passageway.

Provided is a medical robot arm apparatus including a plurality of joint units configured to connect a plurality of links and implement at least 6 or more degrees of freedom in driving of a multi-link structure configured with the plurality of links, and a drive control unit configured to control driving of the joint units based on states of the joint units. A front edge unit attached to a front edge of the multi-link structure is at least one medical apparatus.

A robotically enabled teleoperated system can include a controller and an instrument capable of manipulation by the controller. The instrument can be a medical instrument. The controller can include a handle configured for actuation by an operator. The handle can be attached to a gimbal configured to allow manipulation of the handle in multiple rotational degrees of freedom. The gimbal can include a load cell. The gimbal can be configured for impedance control. The controller can also include a positioning platform coupled to the gimbal and configured to allow manipulation of the handle in multiple positional degrees of freedom. The controller can be configured for admittance control based at least in part on an output signal of the load cell in the gimbal.