Various torque-limiting surgical driver devices, systems, and methods are disclosed. The surgical driver can include a body, a motor that is configured to rotate a drill bit engaged with the surgical driver, and a processor configured to control operation of the surgical driver. The surgical driver can have torque-limiting functionality, such as by monitoring the amount of torque applied to a drill bit and reducing or stopping rotation of the drill bit when certain torque-limiting criteria are met.

An atherectomy system includes an electric drive mechanism that is adapted to rotatably actuate an atherectomy burr and a controller that is adapted to regulate operation of the electric drive mechanism. The controller regulates operation of the electric drive mechanism in accordance with a power input limit value that limits how much power can be put into an atherectomy burr and an energy input limit value that limits how much energy can be put into the atherectomy burr. The controller may also regulate operation of the electric drive mechanism in accordance with a dynamic torque limit.

An endoluminal punch system including a sheath and dilator. The endoluminal punch may include energy delivery system capable of being transmitted from the proximal end to the distal end of the endoluminal punch to assist with tissue crossing and incisions. The dilator may include selectively deployable cutting mechanism to create incisions in tissue that are larger than their basic external diameter. The system may also be configured to reduce the risk of generating plastic emboli during insertion of the endoluminal punch.

A method of controlling the application of energy to a radio frequency (RF) instrument based on a surgical technique may include activating the instrument for a first period T1, during which time a portion of an end effector contacts a tissue, plotting at least two electrical parameters associated with the tissue to classify an amount of the end effector in contact with the tissue, applying a classification algorithm to classify the amount of the end effector in contact with the tissue, and applying an amount of energy to the end effector based on the amount of the end effector in contact with the tissue. The parameters may include a minimum impedance of the tissue and an amount of time that the impedance slope is ˜0. The end effector may contact the tissue with a tip end or with an entire surface.

A system including an instrument having a working tool configured to penetrate a tissue; a sensor configured to generate in real-time one or more torque signals related to torque of the working tool; a controller in operative communication with the sensor and configured to receive the one or more torque signals. The controller processes the torque signals into one or more processed signals representative of torque, energy, power or a combination thereof. The system also includes a display providing to the user in real-time the one or more processed signals. Related devices, systems, methods, and articles are provided.

Disclosed herein are techniques including a robotic manipulator including a surgical tool to interface with and rotate the screw about a rotational axis. A haptic device includes an actuator and a rotational interface coupled to the actuator and the rotational interface is manually manipulatable by a hand of an operator. One or more controllers control movement of the robotic manipulator to maintain the rotational axis of the surgical tool along a planned trajectory; autonomously control the surgical tool to rotate the screw at a rotational rate about the rotational axis and to linearly advance the screw at an advancement rate according to a known thread geometry of the screw; obtain a measurement indicative of a present interaction between the screw and the target site; and control the actuator of the haptic device to enable the rotational interface to emulate the present interaction between the screw and the target site.

Techniques for controlling an end effector include a computer-assisted device having a drive system configured to actuate a moveable element to a first commanded position and a control unit coupled to the drive system. The control unit is configured to actuate, using the drive system, the moveable element to the first commanded position. The control unit is further configured to monitor a force or torque applied by the drive system to actuate the moveable element to the first commanded position, determine a force or torque limit for the drive system based on the monitored force or torque applied by the drive system in response to determining that the moveable element has reached a first position, and further actuate the moveable element to a second commanded position while limiting a force or torque applied by the drive system based on the determined force or torque limit.

For improved treatment of occlusions, a microcatheter guidewire unit for use in a hollow organ including a catheter body with a distal end, a proximal end, and at least two guidewires with guidewire tips is provided. The first guidewire and/or a tip of the first guidewire has a higher rigidity than a second guidewire and/or a tip of the second guidewire. The first guidewire and the second guidewire are passed through the catheter body and arranged such that the tip of the first guidewire and the tip of the second guidewire may be advanced or retracted independently of one another along longitudinal axes.

A system for monitoring potential damage to a tissue within a patient caused by tissue retraction during a surgical procedure, the system comprising: a housing body; an attachment mechanism for attaching the housing body to a tip of a surgical retractor; a force sensor; an inertial sensor; a feedback module; and a control module configured to: track force applied by the retractor tip to the tissue based on force signals received from the force sensor; detect the force applied approaching a force threshold, the force threshold based on a relationship between force applied by the retractor tip to the tissue and orientation of the retractor tip against the tissue; in response to the force applied approaching the force threshold, generating a first warning prompt indicating a possibility of damage to the tissue; and outputting the first warning prompt via a feedback module.

Systems and methods for dynamic adjustments based on load inputs for robotic systems are provided. In one aspect, a robotic system includes a first robotic arm having at least one joint, a set of one or more processors, and at least one computer-readable memory in communication with the set of one or more processors and having stored thereon computer-executable instructions. The computer executable instructions cause the one or more processors to determine a first external load threshold for the at least one joint based on a maximum safe load capability of the first robotic arm, and adjust the first external load threshold during a medical procedure.