A method for generating and updating a three-dimensional representation of a surgical site based on imaging data from an imaging system is disclosed. The method comprises the steps of generating a first image of the surgical site based on structured electromagnetic radiation emitted from the imaging system, receiving a second image of the surgical site, aligning the first image and the second image, generating a three-dimensional representation of the surgical site based on the first image and the second image as aligned, displaying the three-dimensional representation on a display screen, receiving a user selection to manipulate the three-dimensional representation, and updating the three-dimensional representation as displayed on the display screen from a first state to a second state according to the received user selection.

A robotic surgical system is configured to determine whether a surgical instrument has been properly mounted to an arm of the surgical system. As the surgical instrument is moved into engagement with the arm, a magnet on the arm exerts an attractive force on a plate on the surgical instrument. As the instrument engages to the arm, load cell measurements and inertial measurement unit (IMU) information from one or more sensors on the arm are monitored to determine the mass of the instrument as well as the acceleration of the instrument as it mates with the instrument engagement interface. The system compares the load cell measurements and IMU information with what those parameters are expected to be when a surgical device assembly or instrument of that type is mounted. If the load cell measurements and IMU information deviates from what is expected, the system provides a notification to the user and prevents use of the manipulator arm until the surgical device assembly or instrument is properly positioned.

The invention involves a system and method for controlling the movements of a multi-axis robot to perform a surgery at least on the spinal area of a human in vivo. The system includes controls and software coding to cause the robot to move in desired patterns to complete the surgery, which may include bone, disc and tissue removal, and may also include insertion of hardware for fusing adjacent bony structures.

A surgical robotic component comprising an articulated terminal portion, the terminal portion comprising: a distal segment having an attachment connected thereto, an intermediate segment, and a basal segment whereby the terminal portion is attached to the remainder of the surgical robotic component. The terminal portion further comprises a first articulation between the distal segment and the intermediate segment, the first articulation permitting relative rotation of the distal segment and the intermediate segment about a first axis, and a second articulation between the intermediate segment and the basal segment, the second articulation permitting relative rotation of the intermediate segment and the basal segment about a second axis. The intermediate segment comprises: a third articulation permitting relative rotation of the distal segment and the basal segment about third and fourth axes, a first torque sensor configured to sense torque about the third axis, and a second torque sensor configured to sense torque about the fourth axis. The first, second and third articulations are arranged such that in at least one configuration of the third articulation the first and second axes are parallel and the third and fourth axes are transverse to the first axis.

Provided is a surgical imaging apparatus that includes a multi-link, multi joint structure including a plurality of joints that interconnect a plurality of links to provide the multi-link, multi joint structure with a plurality of degrees of freedom, at least one video camera being disposed on a distal end of the multi-link, multi-joint structure; at least one actuator that drives at least one of the plurality of joints; and circuitry that detects a joint force experienced at the at least one of the plurality of joints in response to an applied external force, and controls the at least one actuator based on the joint force so as to position the video camera.

Described herein is a device and method used to effectively remove volume inside a patient in various types of surgeries, such as spinal surgeries (e.g. laminotomy), neurosurgeries (various types of craniotomy), ENT surgeries (e.g. tumor removal), and orthopedic surgeries (bone removal). Robotic assistance linked with a navigation system and medical imaging it can shorten surgery time, make the surgery safer and free surgeon from doing repetitive and laborious tasks. In certain embodiments, the disclosed technology includes a surgical instrument holder for use with a robotic surgical system. In certain embodiments, the surgical instrument holder is attached to or is part of an end effector of a robotic arm, and provides a rigid structure that allows for precise removal of a target volume in a patient.

A force sensing device is disclosed that includes a housing tip, a plurality of sensors stationarily spaced from each other, and a spring element connecting the housing tip to the sensors such that moving the housing tip and the sensor relative to each other causes a resilient deformation of the spring element. The spring element is configured to arrange the housing tip in a zero position relative to the sensors by a spring force of the spring element. The force sensing device is also equipped with a spring tensioning structure configured to adapt the spring force of the spring element.

Presented herein are devices and systems as well as the methods of using the same for the purpose of reducing and/or ameliorating the sensation of pain, specifically, chronic pain. Particularly, in one aspect, the devices, systems, and their methods of use disclosed herein are effective for reducing peripheral nerve pain, such as resulting from traumatic nerve injury and other types of nerve damage.

A joint driving actuator that includes an ultrasonic motor that generates driving force for driving a joint, the ultrasonic motor including a stator fixed to a side of one arm that relatively rotates in the joint and a rotor fixed to a side of another arm that relatively rotates in the joint, the stator including a piezoelectric element that generates ultrasonic vibration, a torque sensor that detects external force applied to the joint, and an encoder that detects a rotational angle of the ultrasonic motor, the encoder being mounted on the one arm, the stator being fixed on the side thereof, and the torque sensor being mounted on the another arm, the rotor being fixed on the side thereof.

Systems and methods related to use of a measurement system in conjunction with a powered instrument for determination of the placement of a tool portion relative to the anatomy of a patient utilizing the powered instrument. The measurement system may include a displacement sensor that indicates the relative displacement of the tool portion relative to the anatomy. The system may also include a sensor for monitoring a tool drive signal representative of a tool drive parameter that is characteristic of the tool portion acting on the anatomy. The tool drive signal may be analyzed relative to a given amount of axial displacement as measured by the displacement sensor to avoid false indications of placement based on noise and or other artifacts in the tool drive signal that may result from characteristics of the anatomy and/or operational behaviors of the surgeon utilizing the instrument.