A medical system comprises an elongate instrument and a control system. The control system is adapted to generate a first model of the elongate instrument and generate a second model of the elongate instrument based at least in part on a reference pose of the elongate instrument. The control system is further adapted to compare the first model with the second model and determine a difference between the first model and the second model. The control system is further adapted to characterize the difference between the first model and the second model and determine a state of instrument buckling based on the characterization of the difference between the first model and the second model.

The present invention relates to medical nanobots with embedded biosensors for real-time and continuous in-vivo anatomic localization, diagnosis, disease surveillance, and therapeutic intervention.

Systems and methods for electromagnetic (EM) distortion detection and compensation are disclosed. In one aspect, the system includes an instrument, the system configured to: determine a reference position of the distal end of the instrument at a first time based on EM location data, determine that the distal end of the instrument at a second time is static, and determine that the EM location data at the second time is indicative of a position of the distal end of the instrument having changed from the reference position by greater than a threshold distance. The system is further configured to: determine a current offset based on the distance between the position at the second time and the reference position at the first time, and determine a compensated position of the distal end of the instrument based on the EM location data and the current offset.

A robotic surgical tool includes an elongate shaft extendable through a handle providing a drive input, a drive cable extending along a portion of the shaft and having a proximal end anchored to the shaft proximal to the handle and a distal end anchored to the shaft distal to the handle, an actuation system housed within the handle and operatively coupled to the drive input such that actuation of the drive input operates the actuation system, and a toggle mechanism arranged at a proximal end of the shaft and actuatable to close or open opposing jaws of an end effector arranged at a distal end of the shaft. The drive cable is threaded through portions of the actuation system and the toggle mechanism such that operation of the actuation system acts on the drive cable and thereby actuates the toggle mechanism to close or open the opposing jaws.

A system for surgical planning and assessment of spinal pathology or spinal deformity correction in a subject, the system comprises a control unit configured to align one or more vertebral bodies of a biomechanical model to one or more vertebral bodies of the radiograph. The control unit is configured to receive one or more spinal correction inputs. The control unit is configured to, based on the received one or more spinal correction inputs, simulate the biomechanical model in a predetermined posture. The control unit is configured to provide for display one or more characteristics of the simulated biomechanical model.

A controller system for a robotic surgical system can include a first instrument controller comprising a first plurality of motors configured to steer a first attachable robotically controlled medical device, a second instrument controller comprising a second plurality of motors configured to steer a second attachable robotically controlled medical device, and a camera controller comprising a plurality of motors and configured to steer an attachable robotically controlled endoscopic camera.

The invention relates to a method of simultaneously calibrating magnetic actuation and sensing systems for a workspace, wherein the actuation system comprises a plurality of magnetic actuators and the sensing system comprises a plurality of magnetic sensors, wherein all the measured data is fed into a calibration model, wherein the calibration model is based on a sensor measurement model and a magnetic actuation model, and wherein a solution of the model parameters is found via a numerical solver order to calibrate both the actuation and sensing systems at the same time.

A surgical instrument includes an end effector, a shaft assembly, an actuation driver, and an actuation assembly. The end effector includes first and second jaws. At least one of the first and second jaws is configured to move relative to the other of the first and second jaws to compress tissue therebetween. The shaft assembly extends proximally from the end effector. The shaft assembly includes a closure member extending along a longitudinal axis. The actuation driver is configured to configured to receive a motor output from a motor. The actuation assembly is operatively coupled with the actuation driver and the closure member. The actuation assembly includes a translating member configured to translate together with the closure member along the longitudinal axis a predetermined distance using the actuation driver such that the closure member applies a predetermined closure force to the first and second jaws corresponding to the predetermined distance.

An ultrasonic surgical instrument including an end effector having an ultrasonic blade, a shaft assembly that defines a longitudinal axis proximally extending from the end effector and an ultrasonic transducer assembly proximally extending from an acoustic waveguide in communication with the ultrasonic blade. The ultrasonic surgical instrument also includes a housing proximally projecting from the shaft assembly such that the ultrasonic transducer assembly is positioned within the housing and a carrier moveably supports the ultrasonic transducer assembly along the longitudinal axis. The carrier collectively moves the ultrasonic transducer assembly, the acoustic waveguide, and the end effector relative to the housing from a proximal, retracted position to a distal, extended position, for inserting the ultrasonic blade into a patient. The ultrasonic surgical instrument also includes an electrical cable extending through the housing at a cable port that transmits electrical communication with the ultrasonic transducer assembly.

A surgical navigation system is provided to create a plan to correct a deformed spinal alignment. A processor is configured to obtain a first set of image data associated with a deformed alignment in a spine of a patient from at least one imaging device. The processor is also configured to process the first set of image data to identify a set of deformed alignment parameters associated with the deformed alignment. The processor is further configured to identify a set of corrected alignment parameters. The processor is also configured to process the first set of image data, the set of deformed alignment parameters, and the set of corrected alignment parameters to generate a correction plan to surgically manipulate the deformed alignment to the preferred alignment. The processor is additionally configured to provide navigation through the correction plan to facilitate surgical manipulation of a patient spine to the preferred alignment. The processor is also configured to receive information relating to forces on a rod-link reducer or surgical implants from strain gauges to aid the correction plan.