A surgical system includes a first surgical instrument having a selected configuration and an image guide disposed relative to a sensor to communicate a signal representative of a position of the image guide. A passive image guide is fixed with vertebral tissue and is disposed relative to the sensor to communicate a signal representative of a position of the passive image guide. The passive image guide includes a first surface. A second surgical instrument is connectable with the first surgical instrument and includes a second surface engageable with the first surface in a mating configuration to provide verification of the selected configuration. Surgical instruments, implants, spinal constructs and methods are disclosed.

A system comprises a robotic arm in a robotic arm coordinate system, a camera in a fixed pose in a navigation coordinate system, at least one processor, and memory including instructions that when executed by the at least one processor, cause the at least one processor to determine a pose of the robotic arm within the navigation coordinate system, map the robotic arm coordinate system to the navigation coordinate system based on the pose of the robotic arm, and control, based on output of the camera, the robotic arm in the navigation coordinate system.

A method for displaying guidance information using a graphical user interface during an medical procedure comprises displaying, in a first mode of the graphical user interface, first image data from a perspective corresponding to a distal end of an elongate device. The first image data includes a virtual roadmap. The method also comprises transitioning from the first mode of the graphical user interface to a second mode of the graphical user interface. The transition is based on an occurrence of a triggering condition. The method also comprises displaying, in the second mode of the graphical user interface, second image data from a perspective corresponding to the distal end of the elongate device. The second image data includes a target indicator corresponding to a target location and an alignment indicator corresponding to an expected location of the medical procedure at the target location.

An end effector for a surgical robotic system, comprising a main body, one or members, and an adjustment mechanism. The main body has an interior sidewall and an opening extending through the main body. The one or more members are located within the main body and extend into and retract from the opening to vary a diameter of the opening through which a tool may be inserted. The adjustment mechanism coupled to the one or more members for varying the diameter of the opening, and comprises a collar coupled to the one or more members such that rotation of the collar in a first direction causes the one or more members to move away from the interior sidewall to reduce the diameter of the opening, and rotation in a second direction causes the one or more members to move towards the interior sidewall to increase the diameter of the opening.

A method may be provided to operate a medical system. First data may be provided for a first 3-dimensional (3D) image scan of an anatomical volume, with the first data identifying a blood vessel node in a first coordinate system for the first 3D image scan. Second data may be provided for a second 3D image scan of the anatomical volume, with the second data identifying the blood vessel node in a second coordinate system for the second 3D image scan. The first and second coordinate systems for the first and second 3D image scans of the anatomical volume may be co-registered using the blood vessel node identified in the first data and in the second data as a fiducial.

A system includes a robotic drive comprising a plurality of cassettes, each cassette to move an elongated medical device (EMD) loaded therein, and an input module to issue instructions to the robotic drive. The input module includes a first two or more selection buttons to select a first two or more EMDs loaded in respective ones of the plurality of cassettes, a first control actuatable to cause issuance of an instruction to the robotic drive to simultaneously move each of the first two or more EMDs linearly, and a second control actuatable to cause issuance of an instruction to the robotic drive to simultaneously rotate each of the first two or more EMDs.

An apparatus includes a processor and a non-transitory memory. The processor is configured to receive pre-operative patient specific data. The pre-operative patient specific data is inputted to a first machine learning model to determine a first predicted post-operative joint performance data output including first predicted post-operative outcome metrics. A reconstruction plan of the joint of the patient is generated based on a medical image of the joint, and at least one arthroplasty surgical parameter obtained from the user. The at least one arthroplasty surgical parameter is inputted into a second machine learning model to determine a second predicted post-operative joint performance data output including second predicted post-operative outcome metrics. The second predicted post-operative joint performance data output is updated to include an arthroplasty surgery recommendation, in response to the user varying the at least one arthroplasty surgical parameter, before the arthroplasty surgery, during the arthroplasty surgery, or both.

A system may be configured to facilitate a medical procedure. Some embodiments may: acquire a scan corresponding to a region of interest (ROI); capture an image of a patient in real-time; identify, via a trained machine learning (ML) model using the acquired scan and the captured image, a Kambin's triangle; and overlay, on the captured image, a representation of the identified Kambin's triangle.

A surgical navigation method includes selecting one or more two-dimensional images from a three-dimensional image. The method further includes adjusting a portion of the two-dimensional images along a viewing direction. The method also includes superimposing the portion of the two-dimensional images along the viewing direction to form a two-dimensional superimposed image. The method further incudes guiding movement of a virtual surgical instrument into the two-dimensional superimposed image.

A medical information processing apparatus according to an embodiment includes a memory storing a model that represents a relation between cell deformation and electric signal propagation; and processing circuitry configured to acquire four-dimensional image data acquired by imaging a three-dimensional structure of a cardiac muscle in time series, extract movement information on the cardiac muscle at multiple positions in the four-dimensional image data, and apply the model to the movement information with respect to the positions to calculate electric signal propagation at the positions.