This invention relates to a breath indicator that is receivable by a part of a breathing assistance apparatus that supplies gas to a patient. The indicator comprises an elongate body having a gas sampling end and an attachment end. The attachment end is adapted to attach to a part of a breathing assistance apparatus and for locating the gas sampling end. The gas sampling end is to be located in a region where gas from the patient is to be exhaled. The gas sampling end being in communication with a sensor comprising a detector material changeable between a first visual indicator state relating to an inhalation phase of the patient, and a second visual indicator state relating to an exhalation phase of the patient. The detector material is capable of changing between the visual indicator states at a sufficient rate to substantially correspond with the inhalation and exhalation phases of the patient.

Provided is a device for the implementation of serious games, i.e. for the presentation of digital games, which do not serve the purpose of entertainment, but the mediation of therapeutic content in the form of images, films, colors, sounds, etc., but may well contain such elements, for the treatment of mental disorders, whereby an authentic and credible, but also entertaining learning experience is the focus of interest in order to achieve a therapeutic result.

A method for testing for visual impairment is provided. The method includes rendering, via a computing device communicatively coupled to a head mounted holographic display device, a virtual target displayed to a user within the holographic display device. The method further includes rendering, via the computing device, at least one virtual light within a field of vision of the user within the holographic display device. The method also includes identifying, via the computing device, whether input was received from the user, wherein the input comprises an indication that the user identified the at least one virtual light. The method further includes generating, via the computing device, a map identifying one or more locations that the user identified the at least one virtual light or did not identify the at least one virtual light.

A method and apparatus may capture a video of a crowd of people near a first person, transmit the video of the crowd to a second device, and receive, from the second device, an indication that a second person in the crowd appears to be at least one of (a) interested in meeting the first person, and (b) a threat to the first person. A display on the frame may display the received indication to the first person.

Virtual Reality systems may be used in healthcare and therapy, e.g., focusing on physical and neurorehabilitation. For instance, victims of brain injury may seek treatment to improve, e.g., range of motion, balance, coordination, joint mobility, flexibility, posture, endurance, and strength. VR systems can be used to entertain and instruct patients in their movements while recreating practical exercises to further therapeutic goals. Patient movement data during physical therapy sessions may be valuable to patients and healthcare practitioners. The system may comprise a plurality of body sensors, a VR headset, and a supervisor tablet. The disclosed system may facilitate translation between real world coordinates and virtual world coordinates, assigning sensors to body parts, measuring range of motion of joints and limbs, correcting sensor orientation, recording and presenting therapy data, and generating and animating a 3-D virtual reality avatar in a virtual world to perform activities, among other benefits.

Augmented reality glasses with auto coregistration of an invisible field on visible reality which allows eyes to directly recognize a real space and precisely performs coregistration on only diagnosis and treatment information of invisible light, which is emitted from a specific area, to the real space. The augmented reality glasses include a glasses body, an invisible light emission unit configured to emit invisible light toward a target object, an input unit configured to input the invisible light emitted from the target object together with visible light to a waveguide, an information processing unit configured to convert invisible light image information received from the input unit into visible light image information which is recognizable by a person, and an image output unit configured to receive the visible light image information processed in the information processing unit and output the received visible light image information to two eyeballs in the waveguide.

A device and method for treating disease involves inserting a scope into a patient’s body, the scope having a light source, a camera and a cartridge connected thereto. The cartridge has two chambers separated by membrane, a first one of the chambers containing a virus, and a second one of the chambers being connected to a plurality of microneedles configured for extending into the patient’s tissue upon insertion of the scope. Cells from the patient are removed via suction from the microneedles and are deposited in the second chambers. The membrane is then broken to mix the virus with the cells to infect the cells, and the infected cells are then transported back into the patient to treat the disease while some cells are removed and stored separately for later use.

Novel tools and techniques are provided for presenting patient information to a user. In some embodiments, a computer system may: receive device data associated with one or more devices configured to perform a cardiac blood flow procedure to provide effective blood flow through a heart and to or from blood vessels of a patient; receive one or more imaging data associated with one or more imaging devices configured to generate images of one or more internal portions of the patient; analyze the device data and the imaging data; map the device data and the imaging data to a multi-dimensional representation of the one or more internal portions of the patient; generate one or more image-based outputs based at least in part on the mapping; and present, using a user experience (“UX”) device, the generated one or more image-based outputs.

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.

Embodiments include a system for determining cardiovascular information for a patient. The system may include at least one computer system configured to receive patient-specific data regarding a geometry of the patient's heart, and create a three-dimensional model representing at least a portion of the patient's heart based on the patient-specific data. The at least one computer system may be further configured to create a physics-based model relating to a blood flow characteristic of the patient's heart and determine a fractional flow reserve within the patient's heart based on the three-dimensional model and the physics-based model.