The present disclosure is related to a system. The system may include a medical device, a medical device, a storage device, a processing device, and an interaction device. The medical device may be configured to perform a medical procedure on a subject or a portion thereof. The storage device may be configured to store subject procedure information relating to the medical procedure on the subject. The processing device may be configured to communicate with the medical device, the storage device, and the interaction device. The interaction device may be configured to communicate to the subject at least a portion of the subject procedure information during the medical procedure.

The invention incorporates a network and modules to register and monitor a group leader and a plurality of participants for a specific group activity, each remotely located from each other and a group physiological state server. Each of a plurality of module and individual registration information of each participant is stored in the form of data in memory on the server and individual participant data is stored at each participant's location. The second module monitors and processes real-time physiological measurements for each of the participants in the specific group activity. A third module tracks a physiological state of the participants, and fourth module evaluates and applies artificial intelligence to provide real-time feedback concerning the physiological state of the group or of an individual. A fifth module may also be employed to provide feedback pertaining to the group leader's physiological state in relation to the overall group physiological state.

The Smart Meditation and Physiological system invention is an advanced group meeting network where meditation brain waves, alpha-meditation and stress, beta-concentration and intellectual activity, gamma-focus and engagement, theta-attention span (such as if subscribers are drifting off to sleep during a session) are recorded and analyzed, yielding collective neurological information to guide the host, physician, instructor, or motivational speaker real-time feedback during a group session.

Moreover, the invention aids in evaluating and facilitating group meditation and yields emotional information of one or more individual participants to monitor the effectiveness of an individual and or group meeting, or a religious prayer session, as well as providing physiological information. It is also a health maintenance diagnostic system all-in-one that continually monitors the health of each individual user in real-time and provides an overall assessment of the effectiveness of the session, a media presentation, or a group meeting, and the information is easily accessible to the host and or to all parties within the group, if desired, housed in a cloud-based system. The information allows the instructor, clergy, or host to perfect and or curtail their next sermon, conference, class, or motivation talk to a particular audience.

A method of generating resection data for use in planning an arthroplasty procedure on a patient bone covered at least partially in cartilage includes receiving a three-dimensional patient bone model comprising a bone model surface, and correlated with a position and orientation of the patient bone via a navigation system. The method further includes identifying a target region on the bone model surface of the model for intra-operative registration, and receiving location data for a first plurality of points based on the intra-operative registration of the cartilage on the patient bone in locations corresponding to points within the target region on the bone model surface. The method further includes determining resection depth based at least in part on the location data for the first plurality of points; and generating resection data using the resection depth, the resection data configured to be utilized by the navigation system during the arthroplasty procedure.

A method includes generating an anatomical model corresponding to an anatomical feature of a patient, proposing a component for coupling to the anatomical feature of the patient, positioning a virtual model corresponding to the component in a proposed location relative to the anatomical model, generating a planned resection geometry based on a virtual relationship between the virtual model and the anatomical model, tracking movement of a surgical instrument relative to the anatomical feature, and simultaneously displaying the planned resection geometry, the anatomical model, and a graphic corresponding to the surgical instrument on a display based in part on the tracked movement of the surgical instrument relative to the anatomical feature.

Methods, apparatus, and systems for medical procedures are disclosed herein and include sensing a plurality of tissue electrical potentials at an organ area of an organ, by one or more electrodes on a catheter, determining a number of peak electrical potentials from the plurality of first tissue electrical potentials such that the a peak electrical potential exceeds a potential threshold, determining a first visual characteristic based on the number of peak electrical potential and displaying a rendering of the organ comprising the organ area such that the rendering of the first organ area comprises the first visual characteristic.

Systems and methods for virtual reality or augmented reality (VR/AR) visualization of 3D medical images using a VR/AR visualization system are disclosed that includes a computing device operatively coupled to a VR/AR device, which includes a holographic display and at least one sensor. The holographic display is configured to display a holographic image to an operator. The computing device is configured to receive at least one stored 3D image of a subject's anatomy and at least one real-time 3D position of at least one surgical instrument, to register the at least one real-time 3D position of the at least one surgical instrument to correspond to the at least one 3D image of the subject's anatomy, and to generate the holographic image comprising the at least one real-time position of the at least one surgical instrument overlaid on the at least one 3D image of the subject's anatomy.

Devices and methods for performing an interventional vascular procedure with visual guidance using one or more optical head mounted displays are disclosed. Devices and methods for compensating the display of an optical head mounted display for cardiac and/or respiratory motion are disclosed.

In an embodiment, an electrogram (EGM) processing system provides, for display by a head-mounted display (HMD) worn by a user, a holographic rendering of intracardiac geometry. The HMD also displays an electrogram waveform. The EGM processing system determines a gaze direction of the user by processing sensor data from the HMD. The HMD displays a marker overlaid on the electrogram waveform at a location based on an intersection point between the gaze direction and the electrogram waveform. The EGM processing system determines a measurement of the electrogram waveform using the location of the marker. The HMD displays the measurement of the electrogram waveform.

An enterprise system and method for maintaining and transitioning humans to a human-like self-reliant entity is presented. Said system including at least one a biological, biomechatronic, and mechatronic entity with a biological or artificial neural network to at least one transform or maintain. Embodiments are provided to assist in the transition of human between a biological state to a bio-mechatronic and mechatronic entity. Said entity's biological, biomechatronic, and mechatronic subsystems are configured to communicate and interact with one another in order for said enterprise system to manage, configure, maintain, and sustain said entity throughout the entity's life-cycle. Subsystem embodiments and components supported by the enterprise system are presented.

This invention relates to a system that interconnects real golf or other sports equipment to a computer. From hereon, sports apparatus, sports equipment, sports equipment items, are examples of a gaming apparatus, unit, tool, or item, and the latter should be understood to be included in the former. In a preferred embodiment the computer is coupled wirelessly to sports implement component, in one embodiment, the sporting equipment is a race car steering wheel coupled with a driver's hand, boxing gloves coupled with a fist, tennis racquet, couple with a tennis ball, basketball coupled with a shooting hand, football couple with a throwing hand, bicycle coupled with a pedal, bowling ball coupled with a bowling throw, soccer couple with a kick, volleyball coupled with a hitting hand, baseball bat coupled with a baseball, all using sensors including accelerometers, gyroscopes and a compass and or a combination of multiple sensing devices.