A surgical instrument comprises a first member including a drive engageable with a first mating surface of a bone fastener. A second member is rotatable relative to the first member and includes an element engageable with a second mating surface of the bone fastener. The members are engageable with the bone fastener in a release configuration, an intermediate configuration and a locked configuration. Systems, surgical adaptors, spinal implants and methods are disclosed.

In one embodiment, a medical system includes a medical instrument includes an elongated shaft having a distal end, at least one cutting element disposed at a distal end of the shaft, a position-tracking transducer disposed at the distal end of the shaft, and electrically insulated from the shaft and the at least one cutting element, and at least one metal coagulation electrode disposed at least partially over the position-tracking transducer, which electrically isolates the at least one metal coagulation electrode from the shaft, a signal generator coupled to apply an electrical current to the at least one metal coagulation electrode, and processing circuitry configured to receive signals generated by the position-tracking transducer, and track a location of the distal end responsively to the received signals.

Systems, methods, and workflows for concomitant procedures are disclosed. In one aspect, the method includes manipulating a flexible instrument using a first robotic arm of a robotic system, manipulating a rigid instrument using a second robotic arm of the robotic system, displaying feedback from the flexible instrument, and displaying feedback from the rigid instrument.

A microrobot configured to move in a viscous material, in particular in an organ of a subject such as a brain, the microrobot having a propulsion structure including a head portion, a rear portion and a deformable portion connecting the head portion and the rear portion. The deformable portion is deformable in elongation/contraction along a main axis connecting the head portion and the rear portion. The head portion includes at its surface at least one propulsion cilium, one end of the at least one propulsion cilium being attached to the head portion and the other end of the at least one propulsion cilium being a free end configured to move freely in the viscous material. The propulsion structure further comprises a motor configured to actuate sequentially elongation/contraction cycles of the deformable portion.

Certain aspects relate to systems and techniques for articulating medical instruments. In one aspect, the instrument includes a wrist having at least two degrees of freedom of movement, and an end effector coupled to the wrist. The end effector can include an upper jaw, a lower jaw, and a firing mechanism configured to form staples in tissue. Actuation of the firing mechanism can be decoupled from the movement of the wrist in the at least two degrees of freedom.

A vine robot catheter device includes an elongate outer catheter dimensioned according to a path to reach a region of a targeted anatomy, an inverted vine robot extension having its proximal end attached to the outer catheter and its distal end partially or fully inverted into itself within the outer catheter during delivery to a target site, and a fluid path in the outer catheter to apply fluid pressure to the vine robot extension to actuate the vine robot extension to evert and extend the distal end out of and beyond the outer catheter.

The present invention relates to a medical device (10), preferably a micro robot for application inside a body, preferably for application inside a human body (2). The medical device (10) includes a body part (11) and a tail part (12). A controlling line (13) is attached to the tail part (12). The controlling line (13) has a tensile strength sufficient to pull back the device from a target location and/or control its velocity and column strength not sufficient to push the medical device (10).

Certain aspects relate to systems and techniques for aligning inputs on medical instruments. In one aspect, the method includes receiving, at a data reader of the instrument drive mechanism, alignment data from the tool when the tool is positioned within a threshold distance of the data reader. The tool include one or more inputs and one or more pull wires configured to be actuated by output shafts of the instrument drive mechanism via the one or more inputs. The method also includes receiving, at a processor, the alignment data from the data reader, and rotating, via the processor, the one or more output shafts of the instrument drive mechanism into alignment with the one or more inputs of the tool based on the alignment data. Each of the output shafts is configured to mechanically couple with a corresponding one of the inputs of the tool.

Systems, devices and methods are provided in which an instrument can translate along an insertion axis. Rather than relying primarily on a robotic arm for instrument insertion, the instruments described herein have novel instrument based insertion architectures that allow portions of the instruments themselves to translate along an insertion axis. For example, an instrument can comprise a shaft, an end effector on a distal end of the shaft, and a handle coupled to the shaft. The architecture of the instrument allows the shaft to translate relative to the handle along an axis of insertion. The translation of the shaft does not interfere with other functions of the instrument, such as end effector actuation.

A surgical instrument adaptor comprises a member including a first mating surface that is removably attachable with a surgical instrument and a second mating surface that is connectable with an actuator. An image guide is attachable with the member and oriented relative to a sensor to communicate a signal representative of a position of the surgical instrument. Systems, surgical instruments, spinal implants and methods are disclosed.