A surgical robotic system that includes a robotic arm, glove configured to be worn on a hand of a user and including a force-feedback mechanism, a tracking device, a processor, and memory. The memory includes instructions which when executed by the processor causes the system to determine that the user is performing a hand gesture with the glove to grasp a virtual user input device (UID) based on the tracking device, and in response to the user grasping the virtual UID, apply, via the force-feedback mechanism, a force upon the glove that corresponds to a physical representation of the virtual UID, and engage the robotic arm to be controlled by the virtual UID.

A method for determining a shape of a lumen in an anatomical structure comprises reading information from a plurality of strain sensors disposed substantially along a length of a flexible medical device when the flexible medical device is positioned in the lumen. When the flexible medical device is positioned in the lumen, the flexible medical device conforms to the shape of the lumen. The method further comprises computationally determining, by a processing system, the shape of the lumen based on the information from the plurality of strain sensors.

A surgical system includes an arm extending from the base and having a distal end configured to be coupled to a tool, a first marker coupled in fixed relation to the base, and a tracking system. The tracking system is configured to collect first data indicative of a position of the first marker and collect second data indicative of a position an anatomical feature of a patient. The surgical system also includes a processor configured to calculate a position of the tool relative to the anatomical feature based on the first data and the second data.

A computer assisted surgery system comprising an image capture apparatus, a display, a user interface and circuitry, wherein the circuitry is configured to: receive information indicating a surgical scenario and a surgical process associated with the surgical scenario; obtain an artificial image of the surgical scenario; output the artificial image for display on the display; receive permission information via the user interface indicating if there is permission for the surgical process to be performed if the surgical scenario is determined to occur.

According to an example of the present disclosure, an apparatus to store slack in a system line for a medical device is disclosed. The apparatus comprises a plurality of slack pockets arranged in series. The system line is configured to form a slack loop into each slack pocket, the plurality of slack pockets isolating the slack loops from each other. The plurality of slack pockets are configured such that when tension is applied to the system line, slack is dispensed by each slack loop straightening from each slack pocket without tangling with another one of the slack loops.

A robotic arm system for surgery is described. The method includes: processing circuitry configured to: apply a virtual barrier preventing a human controlled surgical device from entering an area within a surgical scene; and release the virtual barrier in response to a gesture.

A surgical robotic system includes: a surgical console having a display and a user input device configured to generate a user input and a surgical robotic arm having a surgical instrument configured to treat tissue and being actuatable in response to the user input; and a video camera configured to capture video data that is displayed on the display. The system also includes a control tower coupled to the surgical console and the surgical robotic arm. The control tower is configured to: process the user input to control the surgical instrument and to record the user input as input data; train a machine learning system using the input data and the video data; and execute the at least one machine learning system to determine probability of failure of the surgical instrument.

A system for assessing laxity of a joint of a patient is disclosed. The system comprises a tensioner tool having a substantially rigid portion that may be inserted within the joint to apply a force against a bone surface thereof. The system further comprises a tensioner sock having a flexible body with an opening to receive the tensioner tool and a sensor array disposed on the flexible body. Each sensor of the sensor array is configured to contact the bone surface and detect a pressure when the force is applied against the bone surface. The system further comprises a processor configured to receive the detected pressure from each sensor and calculate the force applied to the bone surface based on the detected pressures.

Systems and methods for inter-arm registration include a computer-assisted system having a control unit coupled to a repositionable arm of a computer-assisted device. The control unit is configured to: receive, from an imaging device, successive images of an instrument mounted to the repositionable arm; determine an observed velocity of a feature of the instrument; determine an expected velocity of the feature of the instrument based on kinematics of the repositionable arm; transform the observed velocity and/or the expected velocity to a common coordinate system using a registration transform; determine an error between directions of the observed and expected velocities in the common coordinate system; and update the registration transform based on the determined error. In some embodiments, the instrument is a medical instrument and the imaging device is an endoscope. In some embodiments, the control unit is further configured to control the instrument using the registration transform.

A system for displaying an intraoperative user interface for a surgical procedure is disclosed. The system comprises an arthroscopic imaging device, a display device, an input device, a processor, and a non-transitory, computer-readable medium. The arthroscopic imaging device is configured to capture one or more images of a patient anatomy within a joint of a patient. The input device is configured to receive input from a user. The processor is configured to receive the images from the arthroscopic imaging device and display a user interface on the display device that includes the images from the arthroscopic imaging device. The processor is also configured to receive the input from the input device, display one or more visual overlays over the one or more images based on the input, and apply one or more digital markers in a fixed location on the one or more images based on the input.