Abstract: A system or method may be used to provide registration, calibration, or tracking of patient anatomy using a camera and a robotic surgical system. The camera may include a structured light camera. The camera may be used to acquire an image of patient anatomy or a reference object. A method may include determining a distance (e.g., from the camera) or a location of the patient anatomy or the reference object. The robotic surgical system may include a robotic arm that may be configured to move based on the distance or location of the patient anatomy or the reference object.

Abstract: A wearable medical device, system and method are disclosed herein. The wearable medical device is placeable on a target site of a subject's body and includes a rotary coupling component and an electrode patch. When the electrode patch is attached to the rotary coupling component, electrodes of the patch's electrode array are electrically coupled to corresponding tracks of the conductive tracks. The wearable medical device also includes an ultrasound scanning and biomarker monitoring module having a set of conductive contacts. When the ultrasound scanning and biomarker monitoring module is attached to the rotary coupling component opposite the electrode patch, the set of conductive contacts are engaged with corresponding tracks of the conductive tracks. The ultrasound scanning and biomarker monitoring module is further configured to rotate about the rotary coupling component with the conductive contacts remaining engaged with the corresponding tracks during rotation.

Abstract: Systems and methods may be used for registering a force input on a portion of a surgical robot, for example using a force sensor of the surgical robot. The force input may correspond to a control command. The control command may generate a change in a control mode of the surgical robot, validate a step of a workflow in planning or navigation software, or the like. A visual indication may be provided, for example using a light of the surgical robot. The visual indication may indicate that the control command has been identified or executed.

Abstract: This invention concerns an automated registration method and device for a surgical robot enabling registration between a first three-dimensional location system comprising an optical distance sensor and a second three-dimensional location system comprising optical acquisition means. The method comprises: a first step of intraoperative registration between the first location system and data recorded on an anatomical surface of a patient and; a second step of intraoperative registration of two three-dimensional location systems. The second registration step is performed at the same time as the first registration step by detection, by the optical acquisition means, of at least one point of a point cloud acquired by the optical sensor during the first intraoperative registration.

Abstract: A system and method for pre-operative or intra-operative surgical procedure feedback provide a recommendation to a surgeon. A system may include a robotic surgical device to perform a portion of a surgical procedure on a patient, and a processor to determine a recommendation, based on past surgical information, for the portion of the surgical procedure performed by the robotic surgical device or for a next action to be taken, but the robotic surgical device or a surgeon. The system may include outputting the recommendation by intra-operatively providing the recommendation to a surgeon operating the robotic surgical device.

Abstract: Methods and surgical system for performing a surgical procedure. The surgical system includes a robotic system with a robotic arm having a surgical instrument attached thereto. A computer system of the robotic system receives at least one image and forms a model of a surgical area. A computer operated tracking system of the robotic system obtains position data related to a patient's bone from tracking elements. Based on the model of the surgical area and the tracked bone position, the robotic arm then performs the surgical procedure with the surgical instrument, and the robotic system adjusts the procedure as a result of the tracked bone position.

Abstract: The invention relates to a recalibration device (1) used during the acquisition of images of an anatomical area of a patient during robot-assisted surgery, including a body (3) made of radxoliacent material, which comprises fiducial markers (9) made of radiopaque material, said body (3) having a bearing surface (7) intended to be manually placed on a surface of said anatomical area of the patient. According to the invention, said fiducial markers (9) are arranged in a specific geometrical pattern enabling a certain detection of the positioning and orientation of the recalibration device (1) in a three-dimensional digital model built from the images derived from the acquisition of the anatomical area.

Abstract: Systems and methods are described herein for resurfacing bones, and in particular, for detecting and resurfacing one or more femoroacetabular impingements (FAIs). A FAI resurfacing controller may be used to perform this detecting and resurfacing of FAIs. The FAI resurfacing controller may include a bone model generator to receive bone imaging and to generate a model of at least one osteophyte and of a surface of a native bone surrounding the at least one osteophyte. The FAI resurfacing controller may include an osteophyte identifier to set a virtual 3D boundary surface between native bone surface and the at least one osteophyte. The FAI resurfacing controller may include a resurfacing navigator to generate and output a navigation file. The navigation file may include the model with the 3D boundary surface between native bone surface and the at least one osteophyte.

Abstract: A surgical instrument retainer can include a proximal component and a distal component. The proximal component can include a head, a first body, and a proximal plurality of projections. The distal component can define a second instrument bore and a body bore and can include a distal plurality of projections. The can head engageable with the end effector coupler to position the instrument retainer within the end effector coupler.

Abstract: A wearable ultrasound apparatus is disclosed for use in connection with various biomedical applications, including musculoskeletal (“MSK”) imaging and analysis, In at least one embodiment, the apparatus provides at least one of an ultrasound module configured for obtaining an at least one ultrasound image of a portion of a user’s body on which the at least one ultrasound module is positioned (hereinafter referred to as the “target site” for simplicity purposes), a electrophysiological (“EP”) module configured for detecting bioelectric signals of the target site, and a near-infrared spectroscopy (“NIRS”) module configured for monitoring oxygenation status and/or biochemical measurements of the target site.

Abstract: An instrument holder assembly for use with a robotic surgical system can comprise one or more modules for holding or guiding an instrument. Each module can comprise a variable diameter jaw having movable teeth configured to hold or guide different sized instruments. Each module can be attached to opposite ends of a main shaft that can couple to an arm of the robotic surgical system. A central passage can extend through each module and the main shaft and the variable diameter jaws can constrict the central passage. Teeth of the variable diameter jaws can be biased to a closed or opened position. A tensioner tool can be used to hold biasing elements in position so that the teeth can be loaded into the module. The teeth can be loaded into slots of the module using a tooth holder device.

Abstract: A system and method may be used to position or orient a camera within a surgical field. A method may include generating a graphical user interface including a first set of instructions to reposition the camera, and determining whether the camera is within a target volume location. The method may include automatically outputting an indication when the camera is within the target volume location. The method may include outputting a second set of instructions for display on the graphical user interface to align a laser, coupled to or integrated into the camera, to the tracker by changing an angle of the camera.

Abstract: A system and method for tracking an object within a surgical field are described. A system may include a lighting component to illuminate a surgical field, and a camera device to capture an image of a tracked device within the surgical field. The system may include a rotational component configured to rotate with respect to the lighting component. The camera device may couple to the rotational component to rotate with respect to the lighting component, such as in response to an obstruction of a tracked object being detected.

Abstract: A system and method for tracking an object within a surgical field are described. A system may include a mesh of cameras distributed around the surgical field, the mesh of cameras including, for example at least three cameras. Cameras in the mesh of cameras may be in known positions or orientations relative to the surgical field or may be mobile with position or orientation to be determined by the system. The system may include a computing system communicatively coupled to the mesh of cameras, the computing system including a processor and a memory device. The computing system may be used to generate tracking data for a tracked object from images or image data taken by one or more cameras of the mesh of cameras.

Abstract: This invention concerns an automated registration method and device for a surgical robot enabling registration between a first three-dimensional location system comprising an optical distance sensor and a second three-dimensional location system comprising optical acquisition means. The method comprises:—a first step of intraoperative registration between the first location system and data recorded on an anatomical surface of a patient and;—a second step of intraoperative registration of two three-dimensional location systems. The second registration step is performed at the same time as the first registration step by detection, by the optical acquisition means, of at least one point of a point cloud acquired by the optical sensor during the first intraoperative registration.

Abstract: The invention relates to a recalibration device (1) used during the acquisition of images of an anatomical area of a patient during robot-assisted surgery, including a body (3) made of radxoliacent material, which comprises fiducial markers (9) made of radiopaque material, said body (3) having a bearing surface (7) intended to be manually placed on a surface of said anatomical area of the patient. According to the invention, said fiducial markers (9) are arranged in a specific geometrical pattern enabling a certain detection of the positioning and orientation of the recalibration device (1) in a three-dimensional digital model built from the images derived from the acquisition of the anatomical area.

Abstract: A system and method for tracking an object within a surgical field are described. A system may include a lighting component to illuminate a surgical field, and a camera device to capture an image of a tracked device within the surgical field. The system may include a rotational component configured to rotate with respect to the lighting component. The camera device may couple to the rotational component to rotate with respect to the lighting component, such as in response to an obstruction of a tracked object being detected.

Abstract: Methods and surgical system for performing a surgical procedure. The surgical system includes a robotic system with a robotic arm having a surgical instrument attached thereto. A computer system of the robotic system receives at least one image and forms a model of a surgical area. A computer operated tracking system of the robotic system obtains position data related to a patient's bone from tracking elements. Based on the model of the surgical area and the tracked bone position, the robotic arm then performs the surgical procedure with the surgical instrument, and the robotic system adjusts the procedure as a result of the tracked bone position.

Abstract: The disclosed subject matter relates to a neurosurgical assistance robot including a movable box the chassis of which is provided with a rigid support arm for connection to a headrest supporting the head of a patient lying on an operating table. Accore invention disclosed subject matter, the support arm is movable with respect to the chassis between a position retracted in the volume of the box and a plurality of extended positions, and a mechanism for locking the arm in any iled being provided for.

Abstract: Methods of accelerating bone cuts, and the devices used therefore, are disclosed. The methods can involve the use of robotic cutting tools.