A tissue segmentation device, controller, and methods therefore are disclosed. The device has an active electrode, a return electrode, a mechanical force application mechanism, voltage and current sensors, and a controller. The controller has a processing component, configured to assign a circuit status to a circuit comprising the at least one electrode. IF (PF0) and ((Vrms/Irms)T), THEN the circuit status is open. IF (PF0) and ((Vrms/Irms)<T), THEN the circuit status is short. PF is a power factor of power applied to the electrosurgical device. T is a threshold value.

Certain aspects relate to systems, devices, and techniques for clot manipulation and removal. At least some of the devices for clot manipulation and removal can be robotically controlled. These devices can include one or more elongate members that can be robotically driven through a patient's vasculature. One such device can include a first elongate member that can serve as an access sheath, a second elongate member that can serve as a clot removal catheter, a third elongate member that can serve as a clot disruptor, and a fourth elongate member that can serve as a guidewire.

According to an embodiment, an autonomous endoscopic system capable of controlling movement of an endoscope inserted into a protective sheath installed in the body of a patient may comprise: an endoscope operating device capable of operating a relative position of the endoscope with respect to the protective sheath, a rolling angle of the endoscope, and a bending angle of a bending portion which is located at the end of the endoscope and is bendable; and a control unit for controlling the endoscope operating device, wherein the control unit controls the endoscope operating device on the basis of a driving record of the endoscope.

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 engagement element connectable with a second mating surface of the bone fastener. A part is disposed with the first member and being alternately connectable with an actuator and an adaptor attachable with an image guide. Systems, surgical adaptors, spinal implants and methods are disclosed.

Certain aspects relate to systems and techniques for an articulating monopolar medical instrument. In one aspect, the medical instrument includes a wrist comprising a proximal clevis and a distal clevis; an end effector coupled to the distal clevis via a distal axle; at least one proximal pulley in the proximal clevis; at least one distal pulley in the distal clevis and coupled to the distal axle; a first cable configured to engage with the at least one proximal pulley and the at least one distal pulley; and a second cable configured to engage with the at least one proximal pulley without engaging the at least one distal pulley.

A urolithiasis removing device according to one embodiment can comprise: an insertion tube; a guide which is inserted into the insertion tube and which is relatively movable with respect to the insertion tube; a wire which is inserted into the guide and which is relatively movable with respect to the guide; a basket positioned in front of the wire and capable of holding urolithiasis; and a control unit for determining the size of the urolithiasis on the basis of the relative movement of the guide with respect to the insertion tube or the relative movement of the wire with respect to the guide.

Various exemplary methods, systems, and devices for controlling electrosurgical tools are provided. In exemplary embodiments of methods, systems, and devices provided herein, a control system can be configured to monitor an electrical parameter during end effector closure, e.g., as jaws of an end effector of an electrosurgical tool move from an open position to a closed position. In response to the electrical parameter dropping to a predetermined minimum parameter threshold, the control system can be configured to cause the end effector to open.

System for guiding an instrument within a vascular network of a patient are disclosed. In some embodiments, the system receives a medical image from a medical imaging device and identifies a distal tip and a direction the instrument in the image. The system may then determine a waypoint for the distal tip of the instrument based at least in part on the position and direction of the distal tip of the instrument. The system may then generate a trajectory command for moving the instrument through the vascular network from the current position to the waypoint. The system may operate in a closed loop. The system may provide the trajectory command to a robotic medical system configured to move the instrument according to the command.

Systems, devices, and methods for evaluating and/or removing slack in an elongate shaft of a medical instrument are discussed herein. For example, an instrument feeder device can be configured to engage with the elongate shaft to facilitate axial motion of the elongate shaft. An amount of slack between the instrument feeder device and an instrument handle of the medical instrument can be determined. Further, slack in the elongate shaft can be removed by moving the instrument handle in a direction away from the instrument feeder device and/or controlling the instrument feeder device to insert the elongate shaft.

An aspiration catheter can include an elongate shaft and an instrument base coupled to the shaft and configured to control actuation of at least a distal portion of the shaft. The shaft can include a lumen configured to couple to an aspiration system to provide aspiration to a target site, such as to remove an object from a patient. The instrument base can be controlled robotically and/or manually to articulate at least the distal portion of the shaft.