An otoscopic instrument with an instrument head. The instrument head having a housing, an optical component disposed along an imaging axis, and an illumination system. The illumination system includes a plurality of LEDs disposed in a ring-like configuration adjacent a distal end of the housing with the illumination system disposed within the housing.

A system for delivering electrical stimulation includes a control system and a stimulation stack. Additionally or alternatively, the system can include and/or be configured to interface with any or all of: an electrical stimulation device, a user device, a client application, and/or any other suitable components. A method for delivering electrical stimulation includes receiving an input and delivering electrical stimulation based on an electrical stimulation plan. Additionally or alternatively, the method can include any or all of: determining an electrical stimulation plan based on the input; requesting a suspension of the electrical stimulation plan, requesting an adjustment to the electrical stimulation plan; requesting sham stimulation in the electrical stimulation plan; requesting monitoring of the electrical stimulation plan; requesting a trim adjustment to the electrical stimulation plan; checking the electrical stimulation plan; providing an output to the user; repeating any or all of the above processes; and/or any other suitable processes.

An otoscopic instrument with an instrument head. The instrument head having a housing, an optical component disposed along an imaging axis, and an illumination system. The illumination system includes a plurality of LEDs disposed in a ring-like configuration adjacent a distal end of the housing with the illumination system disposed within the housing.

A system for monitoring quantitative health data of a user, the system includes a stationary sensor device for monitoring a first set of quantitative health data of the user when the user is resting in bed; and a wearable tracker for monitoring a second set of quantitative health data of the user when the user is resting; wherein the wearable tracker is worn by the user; the first set and second set are sequential in time to obtain around-the-clock monitoring of the quantitative health data of the user.

Provided is a control device that electrically controls a medical observation apparatus configured to capture an image of an observation target and includes a voice recognition section, a recognized-information processing section, a switch input reception section, and a control section. The voice recognition section recognizes a voice inputted from outside. Based on a result of recognition by the voice recognition section, the recognized-information processing section determines processing to be executed by the medical observation apparatus. The switch input reception section receives an input of an operation signal based on an operation performed on a switch. Upon detecting a first operation signal received by the switch input reception section or upon acquiring information regarding processing determined by the recognized-information processing section, the control section causes the voice recognition section to start voice recognition processing and causes the medical observation apparatus to execute the processing determined by the recognized-information processing section.

A training apparatus has an input device and a wearable computing device with a bio-signal sensor and a display to provide an interactive virtual reality (VR) environment for a user. The bio-signal sensor receives bio-signal data from the user. The user interacts with content that is presented in the VR environment. The user interactions and bio-signal data are scored with a user state score and a performance scored. Feedback is given to the user based on the scores in furtherance of training. The feedback may update the VR environment and may trigger additional VR events to continue training.

The present disclosure relates generally to systems and methods for determining the refractive error of a patient, more particularly determining the patient's refractive error by using a computerized screen, and providing a prescription for the patient's preferred type of corrective lenses. In a general embodiment, the present disclosure provides a method for determining a corrective lenses prescription of a patient. The method includes, separately, for each eye of the patient, determining an astigmatism prescription for the patient via a computerized screen and without the use of a refractor lens assembly, including instructing the patient to move a known, fixed distance away from a computerized screen and testing for a cylinder component by sequentially presenting at least two cylinder diagrams to the patient via the computerized screen and enabling the patient to select at least one input per cylinder diagram, where those inputs correspond to cylinder measurements for determining the prescription.

A method is provided, performed by a wearable computing device comprising at least one bio-signal measuring sensor, the at least one bio-signal measuring sensor including at least one brainwave sensor, comprising: acquiring at least one bio-signal measurement from a user using the at least one bio-signal measuring sensor, the at least one bio-signal measurement comprising at least one brainwave state measurement; processing the at least one bio-signal measurement, including at least the at least one brainwave state measurement, in accordance with a profile associated with the user; determining a correspondence between the processed at least one bio-signal measurement and at least one predefined device control action; and in accordance with the correspondence determination, controlling operation of at least one component of the wearable computing device, such as modifying content displayed on a display of the wearable computing device. Various types of bio-signals, including brainwaves, may be measured and used to control the device in various ways.

The present invention relates to a remote collaboration support system in which a real-time surgical video can be tagged. More particularly, the remote collaboration support system according to the present invention comprises: a first HMD which is worn on an operating surgeon at a real surgical operation site, and which comprises a camera for imaging a gazing area and an adjacent area of the operating surgeon and a display unit for outputting a real-time video captured by means of the camera; a second HMD, which is worn on a collaborating surgeon located remotely from the operating surgeon, receives and outputs the real-time video captured in the first HMD, and receives, from the collaborating surgeon, a proposal for the order of surgical operation or a specific treatment sequence included in the surgical operation; and a remote collaboration support server which provides a UI for receiving the selection of whether to accept the proposal through the first HMD when the proposal input from the second HMD is received, and which generates a tag according to whether the operating surgeon has accepted so that same is tagged onto a collected real-time video, wherein the tag includes person-in-charge information about the real-time surgical operation according to the proposal.

Systems, methods and devices for surgical procedurelization via a modular energy system are disclosed herein. In various aspects, the systems, methods and devices include an energy module, a header module communicably coupled to the energy module, and a display screen capable of rendering a graphical user interface (GUI). The GUI may be configured to display a plurality of steps that correspond with actions performed by a user while operating the modular energy system. In some aspects, the steps displayed are steps of a predetermined procedural checklist corresponding with a mental model followed by the user while performing a surgical procedure. In some aspects, the steps displayed are steps of an output verification process.