The present invention provides a health monitoring system for alerting health condition of a user, said system comprised of: At least on Replaceable elastic or semi elastic temple tip, design to be connected to a one end or part of a frame of existing eye glasses, said temple tip including at least one optic sensor, acceleration sensor or ballistocardiograph (BCG) sensor, CPU, memory, energy source and a communication module; Monitoring application implemented on at least one computerized module, for aggregating raw measurement data, analyzing raw data using health oriented AI model for prediction of health conditions and providing alerts to the user and/or entity based on said prediction.

Systems and methods for detecting and managing cognitive decline of a person using a cognitive training device are provided involving a first information source having a device including a sensor configured to detect sensor data corresponding to a first behavior of the person, wherein the first behavior represents a first deviation from a first expected pattern; a second information source configured to receive, store, and transmit data corresponding to a second behavior of the person, wherein the data indicates the second behavior represents a second deviation from a second expected pattern; and a processor configured to analyze the sensor data and the data to determine whether a predetermined threshold has been reached indicating the person is experiencing a first stage of cognitive decline, and generate actionable information to assist a user in determining a treatment for the person to delay the progression of the first stage of cognitive decline.

A method, system, and/or apparatus for automatically monitoring for possible mental or physical health concerns. The method or implementing software application uses or relies upon location information available on the mobile device from any source, such as cell phone usage and/or other device applications. The method and system automatically learns user activity patterns and detects significant deviations therefrom. The deviations are automatically analyzed for known correlations to mental or physical concerns, which can then be automatically communicated to a relevant friend, family member, and/or medical professional.

The invention relates to a device for neurovascular stimulation, at least comprising: at least one brain activity sensor, at least one cardiovascular sensor, at least one computing unit and at least one output unit. The computing unit comprises at least one task algorithm, wherein signals of at least the brain activity sensor and the cardiovascular sensor can be received by the computing unit, and wherein a task, which is in correlation with at least the signals from at least the brain activity sensor and the signals of the cardiovascular sensor, can be determined by means of the task algorithm and can be output by means of the output unit.

Described herein are devices, systems, and methods for sensing and generating a one or more of the 12 leads of a standard ECG with a mobile computing device. In some embodiments, three electrodes are positioned on a mobile computing device so that an individual may comfortably contact all three sensors at once to generate a six lead ECG which may be displayed on a display of said mobile computing device. In some embodiments, analysis carried out further comprises determining a QRS axis and QRST angle.

An electronic device for estimating bio-information is provided. According to one embodiment, the electronic device may include a pulse wave sensor configured to measure a pulse wave signal from an object; a magnetic field detector configured to detect a change in a magnetic field generated by a magnetic field source according to a change in a force exerted by the object to the pulse wave sensor; and a processor configured to acquire a contact pressure between the object and the pulse wave sensor based on the change in the magnetic field and obtain bio-information based on the pulse wave signal and the contact pressure.

An obstructive sleep apnea detection device including an optical engagement surface adapted to engage a user's skin; a light source adapted to emit light from the optical engagement surface; a photodetector adapted to detect light at the optical engagement surface and to generate a detected light signal; a position sensor adapted to determine patient sleeping position; a controller adapted to determine and record in memory blood oxygen saturation values computed from the detected light signal and user position information from the position sensor; and a housing supporting the optical engagement surface, the photodetector, the light source, the position sensor, and the controller.

System and methods for controlling healthcare devices and systems using voice commands are presented. In some aspects a listening device may receive voice command from a person. The voice command may be translated into human readable or machine readable text via a speech-to-text service. A control component may receive the text and send device-specific instructions to a medical device associated with a patient based on the translated voice command. In response to the instructions, the medical device may take an action on a patient. Some examples of actions taken may include setting an alarm limit on a monitor actively monitoring a patient and adjusting the amount of medication delivered by an infusion pump. Because these devices may be controlled using a voice command, in some cases, no physical or manual interaction is needed with the device. As such, multiple devices may be hands-free controlled from any location.

A handheld diagnostic device, specifically for point-of-care applications. The handheld diagnostic device comprises at least one diagnostic measurement unit configured for performing at least one diagnostic measurement, the diagnostic measurement unit comprising at least one test element port for determining at least one diagnostic parameter of at least one patient by using at least one diagnostic test element; at least one camera configured for capturing at least one image of at least one wound of the patient; and at least one control unit, the control unit being configured for controlling the diagnostic measurement and for controlling the capturing of the image of the wound, wherein the control unit is further configured for storing at least one measurement result of the diagnostic measurement and the at least one image in at least one database record of the patient. A diagnostic system and a diagnostic method are further disclosed.

A method of controlling user equipment for a medical checkup and an apparatus for performing the method include controlling user equipment for a medical checkup the includes generating digital biomarker control data by a diagnosis server on the basis of prescription data, and transmitting the digital biomarker control data to user equipment by the diagnosis server, wherein the digital biomarker control data includes information for controlling a digital biomarker module of the user equipment.