A computer-implemented method for collecting data within a facility is disclosed. The method includes receiving, by a computer system, perioperative data from a plurality of surgical devices located within the facility, the perioperative data associated with a plurality of surgical procedures performed in the facility; determining, by the computer system, procedural context data associated with the plurality of surgical procedures based at least in part on the perioperative data; aggregating, by the computer system, the perioperative data according to the procedural context data; and determining, by the computer system, trends associated with the surgical procedures performed in the facility according to the perioperative data and the procedural context data.

A computer-implemented method for collecting data within a facility is disclosed. The method includes receiving, by a computer system, perioperative data from a plurality of surgical devices located within the facility, the perioperative data associated with a plurality of surgical procedures performed in the facility; determining, by the computer system, procedural context data associated with the plurality of surgical procedures based at least in part on the perioperative data; aggregating, by the computer system, the perioperative data according to the procedural context data; and determining, by the computer system, trends associated with the surgical procedures performed in the facility according to the perioperative data and the procedural context data.

A method for recording image data of a moving, (e.g., cyclically moving), region of interest of a patient by a medical imaging system with an X-ray source and an X-ray detector, wherein a robotic device with a kinematic chain of moving components has a tactile connection with the patient, and wherein, the tactile connection is maintained at least for a prespecified period. The method includes acquiring measured values by sensors of the robotic device, evaluating the measured values and forwarding to the medical imaging system, wherein the evaluated measured values include information on the movement and/or position of the region of interest, and irradiation of the region of interest by the radiation source and recording of image data of the irradiated region of interest by the X-ray detector, and wherein the evaluated measured values are used to actuate the imaging system.

Disclosed herein are suture clip delivery devices that can be loaded with several flat, disk-shaped suture clips and can deploy the suture clips one after another onto respective sutures without reloading the device with additional suture clips. An exemplary device includes a handle portion with an actuation mechanism that is coupled to a shaft portion that holds and deploys the suture clips. The shaft portion includes a mandrel on which the suture clips are mounted and a retainer that restricts the suture clips from moving proximally when the actuation mechanism pulls the mandrel proximally, which causes a distal-most suture clip to slide off the mandrel and be deployed onto one or more suture. The mandrel and remaining suture clips can them move distally to prepare to deploy the next suture clip.

A method for intraoperatively measuring joint contact mechanics of a patient's joint is provided. The method includes inserting a sensor between first and second bones of a joint. Then a predetermined force is applied to one of the first and second bones. Afterwards, contact mechanics such as, contact stresses, contact areas and/or forces are measured between the first and second bones in response to the applied predetermined force.

Various torque-limiting screwdriver devices, systems, and methods are disclosed. The screwdriver can include a body, a motor that is configured to rotate a screw engaged with the screwdriver, and a processor configured to control operation of the screwdriver. The screwdriver can have torque-limiting functionality, such as by monitoring the amount of torque applied to the screw and reducing or stopping rotation of the screw when certain torque-limiting criteria are met. In some embodiments, the screwdriver can be switched between manual operation by a user, and automated operation by a motor within the screwdriver. In some embodiments, the screwdriver can be attached to a robotic arm.

An optimal imaging POV intervention system employs an intervention instrument (30), an instrument guide (40), one or more force/torque sensors and an optimal imaging POV controller (20). In operation, the instrument guide (40) establishes a planned trajectory of the intervention instrument (30), and the force/torque sensor(s) sense a force and/or a torque exerted against the intervention instrument (30) and/or the instrument guide (40) when the intervention instrument (30) is positioned within the instrument guide (40). The optimal imaging POV controller (20) controls a determination of an optimal imaging POV of the intervention instrument (30) by deriving an imaging axis of the intervention instrument (30) from a measurement of the force and/or the torque exerted against the intervention instrument (30) and/or the instrument guide (40) as sensed by the force/torque sensor(s).

This application relates to a robot arm structure and a manipulator of a surgical robot including the robot arm structure. The robot anti structure includes a first robot arm unit and a second robot arm unit. The first robot arm unit includes a plurality of first link arms, a first joint unit mounted on one of the first link arms and rotating the one of the first link arms about a first axis and a second joint unit installed on at least one of the plurality of first link arms to adjust a length of the at least one link arm. The second robot arm unit includes a second link arm connected to one of the first link arms and a third joint unit using a lengthwise direction of the second link arm as a first rotary shaft and rotating the second link arm.

An atherectomy system includes a drive mechanism adapted to rotatably actuate an atherectomy burr and a control system that is adapted to regulate operation of the drive mechanism. The drive mechanism may include a drive cable that is coupled with the atherectomy burr and a drive motor that is adapted to rotate the drive cable. The control system includes a drive module adapted to provide an operational signal to operate the drive mechanism, a monitoring module adapted to monitor operation of the drive mechanism and to determine if the drive mechanism is operating within a predetermined range and an excitation module that is operably coupled to the drive mechanism and is adapted to provide haptic feedback to a user of the drive mechanism if the monitoring module determines that the drive mechanism is not operating within a predetermined range.

A method of operating a surgical tool includes mounting the surgical tool to a tool driver. The surgical tool includes one or more drive cables movable to actuate an end effector, and one or more segments are defined along a portion of at least one of the one or more drive cables and each segment exhibits a usage value. Usage of the drive cables is monitored with a computer system in communication with the tool driver, and the usage value of one or more of the segments is altered based on usage of the surgical tool.