Abstract: The disclosure relates to a robotic system for removing bony material from an anatomical structure of a patient, comprising:—a base (4), —an end effector (2) configured to hold a surgical tool (1), —an actuation unit (3) configured to translate the end effector relative to the base at least along one feed axis (A), —a control unit coupled to the actuation unit (3) and configured to turn off the tool (1) and command the actuation unit (3) to translate the end effector (2) along the feed axis (A) while the tool is turned off, the control unit comprising a feedback unit configured to measure a force exerted by the surgical tool (1) onto the anatomical structure during said translation of the end effector (2) and, based on the measured force, detect a contact of the tool with bony material of the anatomical structure.

Abstract: The present disclosure relates to a system for guiding a surgical tool (1) comprising an operative axis with respect to an anatomical structure according to a planned trajectory defined by a target axis (T), comprising: —a robotic device (100) comprising: o an end effector (10) comprising the surgical tool or configured to be coupled to the surgical tool; o an actuation unit (11) comprising at least three motorized degrees of freedom; o a planar articulation (12) coupling the end effector (10) to the actuation unit (11), the planar articulation being configured to constrain movement of the operative axis (R) of the surgical tool inside a single plane; —a localization device (200) configured to determine in real time a position and orientation of the operative axis (R) with respect to a coordinate system of the anatomical structure; —a user interface (300); —a control unit (400) coupled to the localization device (200), the actuation unit (11) and the user interface (300); wherein the control unit (400) is con

Abstract: Systems and methods for an orthopaedic surgical procedure include a surgical instrument adapter having an elongated body with a slot define in one end and a lug positioned on the other end. The slot is sized to receive the pointer end of a navigated pointer instrument such that the pointer end is held in a predetermined position relative to the surgical instrument adapter. A method for performing the orthopaedic surgical procedure includes inserting the pointer end of the navigated pointer instrument into the slot of the adapter, inserting the lug of the adapter into a hole defined in a surgical guide instrument, positioning the surgical guide instrument on a surgically prepared surface of a patient's bone, and determining a position of the navigated pointer instrument using a surgical navigation system. By way of example, the surgical guide instrument may be a femoral finishing block or a tibial template.

Abstract: Methods and systems for guiding position and orientation of a robotic device holding a surgical tool are disclosed herein. For example, a method for guiding a robotic device holding a surgical tool configured for working a planned region of an anatomical structure can include detecting a presence of a distal tip of the tool in a target region on the anatomical structure, changing a visual aspect of a virtual representation of the target region when the tool tip is detected in said target region, computing a virtual goal defining a spatial range of position and orientation of the robotic device in which the tool is capable of working at least a determined part of the planned region, displaying the virtual goal and a representation of a tool base axis, and changing a visual aspect of the virtual goal when the representation of the base axis is inside the virtual goal.

Abstract: A robotic surgical system comprising a robotic surgical apparatus and a graphical user interface (GUI) system may be used to assist a user in performing a surgical procedure. The GUI system may comprise a spatial-data acquisition device, a data acquisition device having a pointer with a tip, a display, and an operating console including a non-transitory storage medium and a processor. The robotic surgical apparatus, the spatial-data acquisition device, the display, and the non-transitory storage medium may be connected to the processor. The processor may be configured to receive as inputs spatial data from the spatial-data acquisition device and provide as outputs to the display a set of indications for positioning the robotic surgical apparatus at the anatomical target. The processor may also be configured to provide as outputs to the display a set of indications for confirming the reference surface location of the anatomical structure.

Abstract: Systems and methods are disclosed for computer aided surgery (CAS), comprising an augmented reality (AR) system configured to display augmented reality information, a position tracking system configured to track positions of objects, an instrument coupled to a tracker detectable by the position tracking system, and a controller configured to: display augmented reality information comprising an indicator of a cut on the bone that would be produced by a current orientation of the instrument and an indicator of a predetermined target plane for the cut, determine, as the instrument is moved, when the current orientation of the instrument is aligned with the predetermined target plane, and based on the determined alignment, display augmented reality information comprising an indicator representing that the current orientation of the instrument is aligned with the predetermined target plane.

Abstract: Described are surgical systems comprising a robotic device comprising a cutting tool, an actuation unit having at least two motorized rotational degrees of freedom about respective rotational axes that are substantially orthogonal to each other, and configured for adjusting a position and orientation of the cutting tool relative to each target plane, a planar mechanism connecting the last segment of the actuation unit to the cutting tool, a passive articulated lockable holding arm supporting the actuation unit, a tracking unit configured to determine in real time the pose of the cutting plane with respect to the coordinate system of the anatomical structure, a control unit configured to determine the pose of the cutting plane with respect to the target plane and to control the actuation unit to bring the cutting plane into alignment with the target plane.

Abstract: Systems and methods are disclosed comprising receiving positional information comprising a plurality of acquired data points associated with a surface of an anatomical feature of a patient, determining a point cloud based on the plurality of data points, extracting a point from the plurality of data points as indicating a landmark on the anatomical feature, determining a boundary associated with the plurality of data points, comparing a distance between the boundary and the landmark point to a predetermined threshold, wherein if the distance between the boundary and the landmark point is not within the predetermined threshold, generating an indication requiring confirmation of the landmark point or a suggestion to acquire additional data points.

Abstract: Systems and methods for planning and assisting orthopaedic surgical procedures include a computing device and a robotic surgical device. The computing device defines a surgical coordinate system relative to a bone of a patient and captures a plurality of point positions in the surgical coordinate system. The plurality of point positions includes a first point position representing a location on a soft tissue surface covering a portion of the patient's bone. The computing device identifies an estimated soft tissue thickness value for each of the plurality of point positions and registers a three-dimensional model of the patient's bone in the surgical coordinate system based on the plurality of point positions and the estimated soft tissue thickness values. The computer system may control the robotic surgical device according to the registered bone model.

Abstract: The invention relates to a system for guiding a surgical tool (200) held by a user relative to at least one target axis (T) defined in a coordinate system of a patient's spine, comprising: (i) a robotic device (300) comprising: —a base (301), —a guiding device (303) configured for constraining the tool to a guiding axis (G), —a compact motorized actuation unit (304) movable relative to the base (301), coupled to the guiding device (303) for adjusting a position and orientation of said guiding device relative to the target axis, —a support unit (305) connected to the base (301), comprising at least one element designed to make contact with the spine or a region of the patient's body adjacent to the spine so as to provide a partial mechanical link between the guiding device and the spine, (ii) a passive articulated lockable holding arm (400) supporting the base (301) of the robotic device, (iii) a tracking unit (500) configured to determine in real time the pose of the guiding axis with respect to the coordinat

Abstract: Described are surgical systems comprising a robotic device comprising a cutting tool, an actuation unit having at least two motorized rotational degrees of freedom about respective rotational axes that are substantially orthogonal to each other, and configured for adjusting a position and orientation of the cutting tool relative to each target plane, a planar mechanism connecting the last segment of the actuation unit to the cutting tool, a passive articulated lockable holding arm supporting the actuation unit, a tracking unit configured to determine in real time the pose of the cutting plane with respect to the coordinate system of the anatomical structure, a control unit configured to determine the pose of the cutting plane with respect to the target plane and to control the actuation unit to bring the cutting plane into alignment with the target plane.

Abstract: A surgical system, including: surgical robot; a connection member connected to the surgical robot; a drape; a plurality of tracking array assemblies configured to engage the connection member wherein the plurality of tracking array assemblies provide different fields of view for a tracking system and wherein the drape is configured to be placed between the connection member and the plurality of tracking array assemblies.

Abstract: The disclosure relates to a robotic surgical system for treating an anatomical structure (B1), comprising: —a base (10) configured to be handheld by a user, —an end effector (13) holding a surgical tool (2), —an actuation unit (12) coupled to the end effector, configured to move the end effector relative to the base, —a tracking unit (3) configured to determine in real time a position of the surgical tool with respect to a coordinate system of the anatomical structure, —a control unit (6) coupled to the tracking unit and to the actuation unit, the control unit being configured to: # compute a path of the tool (2) to remove a planned volume of the anatomical structure, and # control the actuation unit to move the surgical tool according to the computed path to burr the planned volume, wherein the control unit is configured to determine an external surface (S) of the anatomical structure (B1) to be treated and to compute the tool path such that the surgical tool remains under said external surface (S) during tr

Abstract: Systems and methods are disclosed for computer aided surgery (CAS), comprising an augmented reality (AR) system configured to display augmented reality information, a position tracking system configured to track positions (e.g., location and orientation) of objects, an instrument coupled to a tracker detectable by the position tracking system, and a controller configured to: display augmented reality information using the AR system, the augmented reality information comprising: an indication of a predetermined (e.g.

Abstract: Surgical navigation trackers with guards are described that can aid in protecting tracking elements from accumulating liquids thereon, which can negatively impact surgical navigation performance. The surgical navigation trackers described herein can be utilized with a variety of systems and procedures. For example, in one embodiment a system is described that includes a surgical device having an end effector configured for manipulating tissue and a surgical navigation tracker configured to be coupled to any of a surgical instrument and an anatomical structure. The surgical navigation tracker can include a tracking element and a guard configured to be positioned between the tracking element and the cutting tool, as well as a tracking unit configured to determine a position of the surgical navigation tracker.

Abstract: Systems, methods, and devices are disclosed for navigational arrays for attaching to surgical tools, the arrays comprising a frame comprising fiducials for detection by an optical navigation system, and a body having a first end for supporting the frame and a second end defining an opening, wherein the opening is aligned with a first axis of the surgical tool, wherein the opening engages a stationary surface adjacent to the surgical tool, and wherein the opening engages features disposed at predetermined even intervals on the stationary surface adapted to allow repositioning of the array from a first position to a second position, wherein the second position is at least one of a rotational offset or an axial offset from the first position. The stationary surface may be a step disposed on an adapter inserted into the surgical tool. The stationary surface may be a sheath covering a rotatable shaft inserted into the surgical tool. The stationary surface may be a sleeve disposed on the surgical tool.

Abstract: The invention relates to a surgical system for cutting an anatomical structure (F, T) of a patient according to at least one target plane defined in a coordinate system of the anatomical structure, comprising: (i) a robotic device (100) comprising: —an end effector (2), —an actuation unit (4) having at least three motorized degrees of freedom, configured for adjusting a position and orientation of the end effector (2) relative to each target plane, —a passive planar mechanism (24) connecting the terminal part (40) of the actuation unit (4) to the end effector (2); (ii) a tracker (203) rigidly attached to the end effector (2), (iii) a tracking unit (200) configured to determine in real time the pose of the end effector (2) with respect to the coordinate system of the anatomical structure, a control unit (300) configured to determine the pose of the end effector with respect to the target plane and to control the actuation unit so as to bring the cutting plane into alignment with the target plane.

Abstract: The invention relates to a surgical system for cutting an anatomical structure (F, T) of a patient according to at least one target plane defined in a coordinate system of the anatomical structure, comprising: i) a robotic device (100) comprising: —a cutting tool, —an actuation unit (4) comprising from three to five motorized degrees of freedom, said actuation unit comprising at least one portion having a parallel architecture comprising a base (40) and a platform (41) selectively orientable relative to the base (40) according to at least two of said motorized degrees of freedom, —a planar mechanism (24) connecting a terminal part of the actuation unit (4) to the cutting tool (2), ii) a passive articulated lockable holding arm (51) supporting the actuation unit, iii) a tracking unit (200) configured to determine in real time the pose of the cutting plane with respect to the coordinate system of the anatomical structure, iv) a control unit (300) configured to determine the pose of the cutting plane with respec

Abstract: A verification instrument configured to verify the location of a surgical end-effector, including: a body; a navigation element disposed and configured to represent a spatial location of the body; a first clip extending from the body configured to clip onto a tool; a length measurement portion disposed at a first angle from the body, wherein the length measurement portion is configured to contact a tool tip when the first clip is clipped onto the tool.

Abstract: The present disclosure relates to a surgical system for treating an anatomical structure according to a plurality of target planes and/or axes, comprising: a robotic device (1) comprising: an end effector (2) defining a current plane or axis, an actuation unit (11) coupled to the end effector (2), a tracking unit (3) configured to determine a pose of the current plane or axis, a control unit coupled to the tracking unit and configured to control the actuation unit (11) to align the current plane or axis of the end effector (2) with each one of the plurality of target planes and/or axes to treat the anatomical structure, the robotic device being operable in at least the following modes: a working mode wherein a treatment is being performed with the end effector constrained to one target plane or axis by the actuation unit, and a waiting mode wherein no treatment is being performed and the actuation unit is operable to move the end effector in alignment with another target plane or axis, wherein the contr