A biological signal acquirer is attached to a subject and acquires a biological signal of the subject. A transmitter carried by the subject transmits the biological signal. A first communication port and a first camera are installed in a first location and connectable to a network. A second communication port and a second camera are installed in a second location and connectable to the network. A biological information acquiring device is connectable to the network and provided with a switcher. The switcher acquires, when communication establishment between the transmitter and the first communication port is detected, the biological signal through the first communication port as well as a first image taken by the first camera, and acquires, when communication establishment between the transmitter and the second communication port is detected, the biological signal through the second communication port as well as a second image taken by the second camera.

An electroactive photonic polymer sensing device includes an imaging component that uses photonic energy to generate a photocurrent that represents a molecular parameter, wherein the imaging component includes a photosensitive material and at least one of a laser diode and/or photodiode; and a memory component that stores a representation of the molecular parameter, wherein the memory component includes at least one of a protein, vitamin, lipid, carbon allotrope, carbon tetra fluoride. A method of sensing polymers using an electroactive photonic sensing device includes converting, using an imaging component, photonic energy into electrochemical energy to generate a photocurrent that represents a molecular parameter, wherein the imaging device includes a photosensitive material and at least one of a laser diode and/or photodiode; and storing, using a memory component, a representation of the molecular parameter, wherein the memory component includes at least one of a vitamin, lipid, carbon allotrope, carbon tetra fluoride.

An intravascular device for placement within an animal vessel, the intravascular device being adapted to at least one of sense and stimulate activity of neural tissue located outside the vessel proximate the intravascular device.

A method for monitoring a subject, includes: capturing high-bandwidth data pertaining to the subject; cyclically storing a recent portion of the high-bandwidth data in a first memory; monitoring one or more physiological signals of the subject; analyzing the monitored physiological signals to allow detection of one or more target events; upon detection of a target event: copying a then recent portion of the high-bandwidth data from the first memory to a second memory; and storing high-bandwidth captured in a predetermined period subsequent to the detection in the second memory. The one or more physiological signals include EEG. The one or more target events include epileptic seizures. A computer program product and a system may use the method.

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

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.

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.

Aspects include high resolution brain-electronic interfaces and related methods. Aspects include forming a semiconductor circuit on a substrate, depositing a tensile stress layer on the circuit, and separating the semiconductor circuit from a portion of the silicon substrate. Aspects also include removing the tensile stress layer from the semiconductor circuit and transferring the semiconductor circuit to a biocompatible film.

A method of controlling a device includes: obtaining information related to a body surface temperature of a person by detecting the body surface temperature of the person by a thermal camera, estimating a deep body temperature of the person on the basis of the information related to the body surface temperature of the person, detecting the person's condition on the basis of the deep body temperature of the person, and controlling an operation of the device according to the detected person's condition.

Provided are systems, methods, and devices for providing mediation of a traumatic brain injury. Systems may include an interface, processing devices, and a controller. The interface is configured to obtain measurements from a brain of a user with a traumatic brain injury. A first processing device is configured to generate multiple brain state parameters characterizing one or more features of a brain state of the user. A second processing device is configured to generate models of the brain of the user based on the plurality of brain state parameters and the plurality of measurements, and determine, using the models and training data comprising one or more mediation data points, a mediation procedure for reducing one or more symptoms of the traumatic brain injury. The mediation procedure is provided to one or more entities, and one or more control signals are generated by the controller based on the mediation procedure.