Novel tools and techniques are provided for implementing intelligent assistance (“IA”) or extended intelligence (“EI”) ecosystem to placement procedures for cardiac implantable electronic device (“CIED”). In various embodiments, a computing system might analyze received one or more first layer input data (i.e., room content-based data) and received one or more second layer input data (i.e., patient and/or tool-based data), and might generate one or more recommendations for guiding a medical professional in performing a CIED placement procedure in a heart of the patient, based at least in part on the analysis, the generated one or more recommendations comprising 3D or 4D mapped guides toward, in, and around the heart of the patient. The computing system might then generate one or more XR images, based at least in part on the generated one or more recommendations, and might present the generated one or more XR images using a UX device.

A supply tray for a surgical procedure is selected based on the surgical procedure and patient data retrieved from an electronic health records database. Multiple steps of the surgical procedure are retrieved from the electronic health records database. A message is sent to a first manipulator to move a supply from the supply tray to a staging area for performing a step. A first indication is received from a first sensor that the supply is needed at a present time. A position where the supply is needed in an operating area proximate to the staging area is determined using a second sensor. A second message is sent to a second manipulator to move the supply from the staging area to the position. A second indication is received from a third sensor that the step is complete. A third message is sent to a third manipulator to remove the supply.

A surgical robotic system offers automation templates, such as surgical task templates, for collaborative control of the robot arms operating in an automated manner. This automated operation through integration of template selection and programming may reduce fatigue while maintaining accuracy and dexterity. For more routine parts of the surgery, the surgeon may select a template and use the template interface to set various parameters for a given surgery, such as the force to be applied, order of tasks, trajectory of movement, stop points, and/or distance of any given movement in automatic operation for surgeon verification. By automating parts of the surgery, the surgeon may use direct control for more sensitive aspects of the surgery while having a respite or assistance for more routine aspects of the surgery.

A method for performing an orthopaedic surgical procedure on a knee joint of a patient includes resecting a proximal end of a patient's tibia to create a resected surface of the patient's tibia and positioning a tibial paddle of a sensor module on the proximal end of the patient's tibia. The tibial paddle includes a sensor array generating sensor signals indicative of the joint force of the patient's knee joint. The method also includes performing a number of orthopaedic surgical steps while monitoring a display of the sensor module that provides a visual indication of the medial-lateral balance of the joint force of the patient's knee joint.

The present disclosure provides a medical system and devices useable to perform a medical procedure such as an ocular surgery on one or more patients. The medical system includes a camera and a microscope operable to capture surgical images of the portion of the patient subject to the procedure. The medical system is structured to receive the image of the machine-readable information attached to the patient from the camera, decrypt the machine-readable information to identify the patient and retrieve an indication of a scheduled medical procedure for the patient, receive an input from a user of the medical system via a user interface that indicates a planned procedure step of an intended medical procedure using the medical system, determine that the scheduled medical procedure includes the planned procedure step and, in response, activate the microscope such that the surgical images acquired via the microscope are presented on a display.

An example method includes determining, by the one or more processors, an actual orientation of a surgical pin as installed in a bone of a patient; obtaining, by the one or more processors, a planned orientation of the surgical pin; determining, by the one or more processors and based on a comparison between the actual orientation of the surgical pin and the planned orientation of the surgical pin, whether the surgical pin was installed as planned; and responsive to determining that the surgical pin was not installed as planned, outputting, via a visualization device, virtual guidance to assist a surgeon in correcting the installation of the surgical pin.

In general, data modules for surgical instruments and methods of using data modules for surgical instruments are provided. In an exemplary embodiment, a data module is configured to be removably attached to a powered surgical tool such as an electrosurgical tool. The data module is a standalone device including electronic components that are configured to, with the data module attached to the electrosurgical tool, interact with the electrosurgical tool.

A system and method is provided for planning a surgical procedure. The system includes a model of an anatomical region including simulated bone, a tracked tool, a tracking system, a display device, and a computer system configured to receive information from the tracking system, generate and display the model and the tracked tool, and store the tracking system information in a computer readable memory that is portable to a surgical navigation system. The method includes acquiring volumetric data of a patient anatomical region, extracting, providing and registering a three-dimensional model with the volumetric data, using a tracked tool to perform a simulated surgical procedure including removing and replacing a bone section on the model, viewing the model and the tracked tool on a display device, recording the procedure with a tracking system, storing the procedure in a computer readable memory, and porting the procedure into a surgical navigation system.

The subject matter includes systems, methods, and prosthetic devices for joint reconstruction surgery. A computer-assisted intraoperating planning method can include accessing a first medical image providing a first view of a joint within a surgical site as well as receiving selection of a first component of a modular prosthetic device implanted in the first bone of the joint. The method continues by displaying a graphical representation of the first component of the modular prosthetic device overlaid on the first medical image, and updating a graphical representation of the first component based on receiving positioning inputs representative of an implant location of the first component relative to landmarks on the first bone visible within the first medical image. The method concludes by presenting a selection interface enabling visualization of additional components of the modular prosthetic device virtually connected to the first component and overlaid on the first medical image.

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.