A method and system to treat headaches in a patient by performing surgery via at least one nostril. Data from a computer tomography scan of at least one nasal cavity and one sinus cavity of the patient and a completed headache questionnaire are matched to at least one nasal/sinus surgery plan to operate on at least one of: a nasal septum, at least one sinus cavity and at least one turbinate of the patient. The surgery plan is executed by installing a topical local anesthetic and decongestant onto the at least one turbinate forming an anesthetized decongested nasal cavity; infusing an anesthetic into the anesthetized decongested nasal cavity of the patient; dilating the at least one sinus ostium; incising at least one of: a first mucosal flap or a second mucosal flap of the nasal septum of the anesthetized decongested nasal cavity to expose deviated septal cartilage and bone; removing deviated cartilage and/or bone of the nasal septum; fracturing the at least one turbinate laterally away from the nasal septum; inspecting between the first mucosal flap and the second mucosal flap for a residual broken bone, a residual segment of cartilage or combinations thereof, surgically closing the first mucosal flap and the second mucosal flap of the nasal septum; and suctioning unwanted matter from the anesthetized decongested nasal cavity. An interactive system guides the surgery and provides a record thereof.

A number of improvements are provided relating to computer aided surgery. The improvement relates to both the methods used during computer aided surgery and the devices used during such procedures. Some of the improvement relate to controlling the selection of which data to display during a procedure and/or how the data is displayed to aid the surgeon. Other improvements relate to the structure of the tools used during a procedure and how the tools can be controlled automatically to improve the efficiency of the procedure. Still other improvements relate to methods of providing feedback during a procedure to improve either the efficiency or quality, or both, for a procedure.

Systems, methods, software and techniques for generating a milling path for a tool of a surgical system are provided. The milling path is designed to remove a resection volume associated with an anatomical volume. A reference guide is defined with respect to the resection volume. Sections are defined along the reference guide in succession. Each section intersects the reference guide at a different intersection point and is at a specified orientation relative to the reference guide at the intersection point. Each section further intersects the resection volume. A section path is generated to be bounded within each section and defined relative to the resection volume. A plurality of transition segments are generated and each transition segment connects section paths of successive sections along the reference guide.

Computer-implemented methods for modeling a surgical correction for a patient, and associated systems are disclosed herein. In some embodiments, the method includes obtaining patient data. The image data can depict a native anatomical configuration of a region of a patient's spine. The method also includes generating a virtual model of the patient's spine in the native anatomical configuration and/or a corrected anatomical configuration. The method can also include identifying one or more soft tissue surgical steps, predicting an effect of the soft tissue surgical steps, and generating a surgical plan for achieving the corrected anatomical configuration. The soft tissue surgical step can adjust an intraoperative mobility of vertebrae of the spine to achieve the corrected anatomical configuration. The surgical plan includes at least one of the soft tissue surgical steps to help facilitate movement of the vertebrae to the corrected anatomical configuration.

A system for performing robotic laser surgery is disclosed. The system comprises at least one surgery equipment, a surgeon terminal, and a communication module. Further, the system includes a surgical computer communicatively coupled to the at least one surgery equipment via the communication module. The surgical computer is configured to transfer data between the surgeon terminal and the at least one surgery equipment. The surgeon terminal is configured to modulate the tunable laser to conduct the surgical procedure in fully autonomous mode or semi-autonomous mode using robot controls. Further, a plurality of sensors is used to real-time data while performing surgical procedure and transmit the real-time data to the surgeon terminal.

The systems and methods of the present disclosure are used for guiding a medical instrument towards a target, the method positioning a medical instrument at a first location within a patient anatomy, wherein the medical instrument comprises at least one sensor, determining a first biomarker measurement using the at least one sensor, determining a second biomarker measurement using the at least one sensor, comparing the first biomarker measurement with the second biomarker measurement to determine a proximity to the target to provide a first comparison, and providing guidance for moving the medical instrument based on results of the first comparison.

A method of manufacturing a three dimensional bio-model from medical image data is described. The method comprises: identifying a skin layer in the medical image data; determining a thickness of the skin layer; generating three dimensional model data from the medical image data, the three dimensional model data comprising an indication of a synthetic skin layer, the synthetic skin layer comprising a surface layer and a backing layer, wherein a combined thickness of the surface layer and the backing layer is determined from the thickness of the skin layer; and three dimensional printing the three dimensional model data to provide a three dimensional bio-model.

A method for surgically treating a spine comprising the steps of: pre-operatively imaging vertebral tissue; displaying a first image of a surgical treatment configuration for the vertebral tissue from a mixed reality display and/or a second image of a surgical strategy for implementing the surgical treatment configuration with the vertebral tissue from the mixed reality display; determining a surgical plan for implementing the surgical strategy; and intra-operatively displaying a third image of the surgical plan with the vertebral tissue from the mixed reality display. Systems, spinal constructs, implants and surgical instruments are disclosed.

A tissue suturing guidance system includes an image capturing device, a display, and a processor in communication with the image capturing device and the display. The image capturing device is configured to capture a suture site. The display is configured to display an image of the suture site. The processor is configured to: determine, based on the image of the suture site, a geometric tissue representation of the suture site; access measured properties of the suture site; determine, based on the measured properties of the suture site, a biomechanical tissue representation of the suture site; and generate, based on the geometric tissue representation and biomechanical tissue representation of the suture site, a suturing configuration for the suture site.

The present invention provides a robotic navigation system for identifying a target nerve for guiding and/or performing the implanting a neuromodulation device at the target nerve wherein the neuromodulation device includes a pulse generator and at least one lead in electrical or operative connection with the pulse generator. In some embodiments, the location of the robotically advanced lead and electrode may be imaged and displayed on a display and/or may be visually annunciated using one or more lights to indicate whether the placement location of the lead or electrode is within or outside of a predetermined distance of the target nerve.