A method (10) that encodes electrode locations to a mean scalp mesh for adaptation to subsequent image scans.

A vibration control device that while responding to music being played, generates a vibration that gives desired arousal effect and/or relaxing effect regardless of the contents is provided, the vibration control device controlling a vibration device that generates vibration according to the music being played and gives a stimulus to a user includes a vibration signal acquisition unit for acquiring a vibration signal representing the vibration in which a stimulus intensity falls within a predetermined stimulus intensity range, and an output unit for outputting the vibration signal acquired by the vibration signal acquisition unit to the vibration device.

Devices and processing systems are configured to enable physiological event prediction based on blepharometric data analysis. For example, some embodiments provide methods and associated technology that enable retrospective analysis of blepharometric data driving subsequent hardware/software configuration, thereby to provide for personalized and/or generalized biomarker identification.

Systems and methods are disclosed for the treatment and prevention of migraine and other headache conditions, and more specifically to systems and methods of treating and preventing migraine and other headache conditions through noninvasive peripheral nerve stimulation.

A brain wave monitoring system includes an electronic device and at least one electroencephalograph connected to the electronic device, each electroencephalograph includes 8 channels respectively connected to a corresponding electrode for receiving a brain wave signal. The electronic device scans a number of the at least one electroencephalograph and sequentially displays multiple channels of the at least one electroencephalograph according to an identifier of each of the at least one electroencephalograph. The brain wave monitoring system can automatically detect the number of electroencephalographs connected to the electronic device, and display the brain wave signals of all channels of all electroencephalographs according to the number of electroencephalographs and 8 channels of each electroencephalograph. The brain wave monitoring system can also prompt a guide message according to a channel impedance value and a signal quality index to assist a user improving a quality of the brain wave.

A brain wave monitoring system includes an electronic device and at least one electroencephalograph connected to the electronic device, each electroencephalograph includes 8 channels respectively connected to a corresponding electrode for receiving a brain wave signal. The electronic device scans a number of the at least one electroencephalograph and sequentially displays multiple channels of the at least one electroencephalograph according to an identifier of each of the at least one electroencephalograph. The brain wave monitoring system can automatically detect the number of electroencephalographs connected to the electronic device, and display the brain wave signals of all channels of all electroencephalographs according to the number of electroencephalographs and 8 channels of each electroencephalograph. The brain wave monitoring system can also prompt a guide message according to a channel impedance value and a signal quality index to assist a user improving a quality of the brain wave.

A personal protection device includes one or two elongate members for engaging into the nostrils of the nose of a user. The elongate members each includes gridded ports for allowing air to pass through the elongate member when breathing in and for allowing air to exit via the elongate member when breathing out. Sensors are placed in the air flow pathway to detect pathogen presence, and the primary air filter is positioned in the elongate member. In yet other embodiments, a disposable version is disclosed. The eyewear can also be used as part of an extended reality system, and when game playing, particularized scents can be rendered to the nose to enhance the gaming experience. In another aspect, systems and methods protect against pathogen by sampling an environment of a travel path with a plurality of pathogen detectors along the travel path to detect a presence of one or more pathogens, wherein at least one detector includes a nano-sensor with receptacles to bind to the pathogens and wherein the nano-sensor changes resistivity, inductance or capacitance upon pathogen binding; directing air towards said pathogen detectors; contact tracing a user mobile device having a mobile identification (ID) carried by each user, wherein the mobile device comprises a memory storing mobile IDs of all devices within a predetermined radius of the user mobile device; and performing deep learning with a neural network receiving data from the pathogen detectors and to the user mobile device to detect a presence of one or more pathogens.

The method of modulating epileptogenicity in a brain of an epileptic patient includes: providing a virtual brain; providing a model of an epileptogenic and of a propagation zones and loading the model in the virtual brain to create a virtual epileptic brain; acquiring data of the brain of the epileptic patient; identifying, in the data, a location of at least one possible epileptogenic zone; fitting the virtual epileptic brain against the data acquired from the epileptic patient and parametrizing the at least one possible epileptogenic zone in the virtual epileptic brain as an epileptogenic zone; and simulating, within the virtual epileptic brain, the effect of a network modulation mimicking a clinical intervention of the brain of the patient.

The method of modulating epileptogenicity in a brain of an epileptic patient includes: providing a virtual brain; providing a model of an epileptogenic and of a propagation zones and loading the model in the virtual brain to create a virtual epileptic brain; acquiring data of the brain of the epileptic patient; identifying, in the data, a location of at least one possible epileptogenic zone; fitting the virtual epileptic brain against the data acquired from the epileptic patient and parametrizing the at least one possible epileptogenic zone in the virtual epileptic brain as an epileptogenic zone; and simulating, within the virtual epileptic brain, the effect of a network modulation mimicking a clinical intervention of the brain of the patient.

A vehicular notification apparatus detects an emotion of a driver based on a line-of-sight detection result and a brain activity detection result, and performs control to suppress notification in response to that the detected emotion of the driver is uncomfortable.