A system for verifying a tool for use in a surgical procedure includes a mechanical interface configured to be affixed to a portion of a patient's anatomy, wherein the mechanical interface comprises at least a first portion having a first diameter and a second portion having a second diameter. The system further includes a probe configured to be inserted into the mechanical interface to establish a checkpoint location, and a computing system configured to determine a location of a portion of the probe when the probe is inserted a maximum distance into the mechanical interface, wherein the location of the portion of the probe establishes the checkpoint location. The computing system is further configured to verify a surgical tool by comparing the checkpoint location to a location of a portion of the surgical tool when the surgical tool is inserted a maximum distance into the mechanical interface.

The invention relates to a method for determining a trajectory of a motorized X-ray imaging system for acquiring images of a patient to whom a phantom comprising radiopaque fiducials having a known spatial arrangement has been attached so as to be visible on at least one 2D image of a body region of interest acquired by the X-ray imaging system by acquiring one first 2D image of the phantom by the X-ray imaging system in a given position; detecting the fiducials of the phantom in the acquired first image; based on the detected fiducials, determining the position of the phantom in a referential of the X-ray imaging system; determining a set of positions of the X-ray imaging system configured to acquire a set of 2D X-ray images of the region of interest such that the set of 2D X-ray images complies with at least one imposed requirement on the position of the phantom relative to a part of the set of images and combining the set of determined positions to determine a trajectory of the X-ray imaging system with respect to the position of the phantom.

A surgical instrument includes a housing, an outer shaft, an inner shaft, a trial sizer, a rod, and a head. The outer shaft is operatively coupled with the housing such that rotation of the housing causes axial displacement of the outer shaft. The outer shaft includes a keel cutter configured to form a channel in a vertebral body. The inner shaft disposed within the outer shaft. The trial sizer is configured to be received in intervertebral space. The trial sizer includes a pair of wings transitionable between a retracted position and an extended position in which the pair of wings extends transversely outward. The head is connected to the rod, wherein the head is operatively coupled with the pair of wings such that axial displacement of the rod causes transition of the pair of wings between the retracted and extended positions.

A gastrectomy device includes an elongated member defining a centerline that extends through proximal and distal ends thereof. A shape modification member coupled to the elongated member is movable relative to the centerline of the elongated member. The shape modification member is movable between a first state, adjacent to the elongated member, and a second state, spaced from the elongated member. The shape modification member conforms to a portion of a patient's stomach in the second state.

A surgical instrument includes a housing, an outer shaft, an inner shaft, a trial sizer, a rod, and a head. The outer shaft is operatively coupled with the housing such that rotation of the housing causes axial displacement of the outer shaft. The outer shaft includes a keel cutter configured to form a channel in a vertebral body. The inner shaft disposed within the outer shaft. The trial sizer is configured to be received in intervertebral space. The trial sizer includes a pair of wings transitionable between a retracted position and an extended position in which the pair of wings extends transversely outward. The head is connected to the rod, wherein the head is operatively coupled with the pair of wings such that axial displacement of the rod causes transition of the pair of wings between the retracted and extended positions.

A method for calibrating a surgical device is provided. The method includes acquiring first data including a position and/or an orientation of a first object disposed on the surgical device at a first location; acquiring second data including a position and/or an orientation of a second object disposed on the surgical device at a second location; determining third data including a position and/or an orientation of the first object relative to the second location; and determining a position and/or an orientation of the second object relative to the second location based at least in part on the first data, the second data, and the third data.

A surgical system includes a first tracker configured to be affixed to a first object, a detection device configured to determine a change in position of the first tracker, and circuitry communicable with the detection device. The circuitry is configured to compare the change in the position of the first tracker to a condition and generate a fault signal in response to a determination that the change in the position of the first tracker violates the condition.

A gastrectomy device includes an elongated member defining a centerline that extends through proximal and distal ends thereof. A shape modification member coupled to the elongated member is movable relative to the centerline of the elongated member. The shape modification member is movable between a first state, adjacent to the elongated member, and a second state, spaced from the elongated member. The shape modification member conforms to a portion of a patient's stomach in the second state.

A method of operating a surgical device having a surgical tool includes allowing manual movement of the surgical tool along at least one direction, controlling the surgical device to align the surgical tool with a target using a control object having a planned geometric relationship with an anatomic feature, tracking movement of the anatomic feature during a surgical procedure, moving the control object to compensate for the movement of the anatomic feature during the surgical procedure, and controlling the surgical device to realign the surgical tool with the target using the moved control object.

The invention relates to a method for determining a trajectory of a motorized X-ray imaging system for acquiring images of a patient to whom a phantom (30) comprising radiopaque fiducials having a known spatial arrangement has been attached so as to be visible on at least one 2D image of a body region of interest acquired by the X-ray imaging system, the method comprising the following steps: acquiring one first 2D image of the phantom (30) by the X-ray imaging system in a given position; detecting the fiducials of the phantom (30) in said acquired first image; based on said detected fiducials, determining the position of the phantom in a referential of the X-ray imaging system; determining a set of positions of the X-ray imaging system adapted to acquire a set of 2D X-ray images of the region of interest such that said set of 2D X-ray images complies with at least one imposed requirement on the position of the phantom relative to a part of said set of images, combining said set of determined positions to determine a trajectory of the X-ray imaging system with respect to the position of the phantom (30).