Surgical systems and methods are provided for controlling actuation and movement of various surgical devices.

A spinal construct includes a first member having a first thread form and an implant cavity configured for disposal of the spinal implant. A second member is engageable with a spinal implant and includes a second thread form configured for engagement with the first thread form. A gauge is coupled to the second member. The gauge is configured to measure a force between the second member and the spinal implant when the second member is engaged with the first member. The second thread form is timed with the first thread form to position the gauge in a selected orientation relative to the spinal implant. Systems and methods are disclosed.

A surgical robot system includes a robot having a robot base and a robot arm coupled to the robot base, and a surgical retractor. The surgical retractor includes a retractor frame, a coupler, blades, a force and/or torque sensor, and a force and/or torque feedback determination unit. The retractor frame includes arms that are translatably and/or pivotably connected to the retractor frame. The coupler releasably attaches the retractor frame to the robot arm. The blades are each coupled to and extend away from a distal end of one of the arms. The force and/or torque sensor is connected to the blades and indicates an amount of force and/or torque being applied to the blades from contact with material of a surgical site. The force and/or torque feedback determination unit determines the amount of force and/or torque being applied to the blades based on the indication.

A system and method for determining a patient force during a motion includes a tether adapted to be biased during a motion so that a tension force is applied. The tether is connected a motor and generates a tether force about the motor. The system controls the motor by generating a motor torque in a direction opposite the tether force. A recording module stores the motor torque at a plurality of intervals during the motion and a position of the tether. A display module generates a plot of a position of the patient versus a force generated by the patient. The position of the patient corresponds to the cumulative rotation of the shaft in the first direction about the axis of rotation of the shaft at each of the intervals. The force generated by the patient corresponds to the amount of motor torque at each of the intervals.

A telesurgical system operates in a first operating mode and in a second operating mode. In the first operating mode, a moveable component is driven within a first range of an operating parameter. In the second operating mode, the moveable component is driven with a second range of the operating parameter, less than the first range. Usable instrument life is increased by decreasing mechanical degradation of the moveable component as a result of operating in the second range. A surgeon may select either operating mode.

A control apparatus for a continuum robot including a curved portion that is curved by driving a wire with a driving mechanism includes an image DB/torsional-amount acquisition unit that obtains the torsional amount of the continuum robot and a kinematic operation unit that sets the driving displacement amount of the wire driven by the driving mechanism on the basis of the torsional amount obtained by the image DB/torsional-amount acquisition unit.

An apparatus includes a base and a support including a non-straight channel extending therethrough. An elongated medical device extends through the channel and imparts a first load to a channel wall causing a reaction load on the support. A sensor is configured to measure a reaction load applied to the support.

A uterine manipulator includes a body defining proximal and distal end portions, a handle operably coupled to the proximal end portion, an end effector assembly operably coupled and configured to articulate relative to the distal end portion, and a force sensor configured to measure a force indicative of a torque required to articulate the end effector assembly relative to the distal end portion of the body. A method of transcervically determining uterine mobility includes transcervically positioning a surgical instrument such that an end effector assembly of the surgical instrument extends into a uterus, articulating the end effector assembly relative to a body of the surgical instrument to thereby move the uterus, and measuring a force indicative of a torque required to move the uterus.

Described herein are systems, apparatus, and methods for precise placement and guidance of tools during a surgical procedure, particularly a spinal surgical procedure. The system features a portable robot arm with end effector for precise positioning of a surgical tool. The system requires only minimal training by surgeons/operators, is intuitive to use, and has a small footprint with significantly reduced obstruction of the operating table. The system works with existing, standard surgical tools, does not required increased surgical time or preparatory time, and safely provides the enhanced precision achievable by robotic-assisted systems.

A surgical simulation device includes a support structure and animal tissue carried in a tray. A simulated human skeleton is carried by the support structure above the animal tissue and includes simulated human skin. A camera images the animal tissue and an image processor receives images of markers positioned on the ribs and animal tissue and forms a three-dimensional wireframe image. An operating table is adjacent a local robotic surgery station as part of a robotic surgery station and includes at least one patient support configured to support the patient during robotic surgery. At least one patient force/torque sensor is coupled to the at least one patient support and configured to sense at least one of force and torque experienced by the patient during robotic surgery.