A robotically controlled depth limiter for a reamer, the depth limiter including a cylindrical housing configured to encompass a portion of a driveshaft of a reamer. The cylindrical housing can define a bore extending therethrough. The depth limiter can include a depth stop engaging the cylindrical housing within the bore, and define an opening configured to receive the driveshaft of the reamer. The depth stop can be configured to receive a signal via processing circuitry of a robotic arm to operate the depth stop to limit distal translation of the driveshaft relative to the cylindrical housing to control a cutting depth of the reamer.

A procedure is performed with a tool coupled with one or more sensors. 3D image data is acquired of a skeletal portion. First and second x-ray images of the tool and the skeletal portion are acquired from respective first and second views. A computer processor (22) (i) registers the x-ray images to the image data, (ii) identifies a first location of the tool with respect to the skeletal portion, within the x-ray images, (iii) determines the tool's first location with respect to the image data, (iv) subsequently to moving the tool to a second location, obtains measurements by the sensors pertaining to the movement of the tool, (v) derives the second location of the tool with respect to image data by applying the information from the sensors to the determined first location of the tool, and (vi) generates an output. Other applications are also described.

Disclosed is a system for imaging a system. The system may be operated to acquire image data of a subject in one or more manners. The image data acquired may be used to various purposes, such as generating an image for display, navigating a procedure, or other appropriate procedures.

A robotic medical system can include a motorized arm that is supported by a column of the system. The robotic arm can be operated by rotating a link of the motorized arm by actuating an actuator to drive rotation of a rotary joint. A brake can then be applied to the rotary joint to stop rotation of the link. The arm can also include an arbor that can be actuated to increase a torsional stiffness of the rotary joint.

A system for register operating space includes a first positioning mark, a local camera, a second positioning mark, a global camera and a computer system. The first positioning mark is set on a patient. The local camera captures a first image covering the first positioning mark. The second positioning mark is disposed on the local camera. The global camera captures a second image covering the second positioning mark. The focal length of the global camera is shorter than the focal length of the local camera. The computer system is communicatively connected to the local camera and the global camera to provide a navigation interface based on the first image and the second image.

A head-mounted extended reality (XR) display device includes a rigid mounting element coupled to a frame. The XR display device further includes right-side and left-side visible light cameras coupled to the rigid mounting element, right-side and left-side near-infrared (NIR) cameras coupled to the rigid mounting element, and an NIR light-emitting diode (LED) configured to illuminate a region within a field of view of the NIR cameras. The visible light cameras are configured to capture stereoscopic visible light images within a field of view of the user when the user is wearing the frame, and the NIR cameras are configured to capture stereoscopic NIR images within the field of view of the user when the user is wearing the frame.

An instrument includes a sleeve extending between proximal and distal ends. The sleeve defines a passageway. The proximal end includes an aperture extending into an outer surface of the sleeve. The distal end includes an engagement surface and an opening extending through the engagement surface. The opening is in communication with the passageway. A member is movably disposed in the aperture. The member includes a spring and a body. The body defines a bore. A shaft extends between opposite proximal and distal ends. The proximal end of the shaft extends through the bore. The distal end of the shaft extends through the opening. Systems and methods of use are disclosed.

A virtual model a planned instrument attachment can be provided to ensure correct selection of a physical instrument attachment. An XR headset controller can generate a shape and a pose of the virtual model of the planned instrument attachment based on predetermined information associated with the planned instrument attachment and based on a pose of an instrument relative to the XR headset. An XR headset can display the virtual model on a see-through display screen of the XR headset that is configured to allow at least a portion of a real-world scene to pass therethrough.

A camera tracking system for computer assisted navigation during surgery. The camera tracking system includes a processor operative to receive streams of video frames from tracking cameras which image a plurality of physical objects arranged as a reference array. For each of the physical objects imaged in a sequence of the video frames, that processor determines a set of coordinates for the physical object over the sequence of the video frames. For each of the physical objects, the processor generates an arithmetic combination of the set of coordinates for the physical object. The processor generates an array template identifying coordinates of the physical objects based on the arithmetic combinations of the sets of coordinates for the physical objects, and tracks pose of the physical objects of the reference array over time based on comparison of the array template to the reference array imaged in the streams of video frames.

A system for positioning a medical object at a desired depth includes a light guiding facility and a processing unit. The processing unit is configured to receive planning information that specifies a desired depth for an arrangement of a predefined section of a medical object in an examination object with respect to an entry point of the medical object in the examination object. The medical object has a mark that has a predefined relative positioning with respect to the predefined section. The processing unit is configured to control the light guiding facility for emitting a light distribution as a function of the planning information and the predefined relative positioning such that the light distribution illuminates the mark if the predefined section is arranged at the desired depth.