The present disclosure provides a device with electrodes configured to record electrical activity that are confined to a restricted area, using recorded biological electrical signals to control cursor position in a speech-assistance interface, and using recorded biological signals to detect arousals during sleep.

A medical diagnostic method, system and related equipment particularly adapted to diagnose disorders of the blood circulation serving the head and neck, and especially the brain. A preferred use of the system is early, rapid, accurate, diagnosis of stroke, especially whether the stroke is due to blockage of a blood vessel or leakage from the blood vessel.

A device that suppresses a pathological synchronous and oscillatory neuron activity, and includes a non-invasive stimulation for stimulation, using stimuli, of neurons in the patient's brain and/or spinal cord, where those neurons are showing pathologically synchronous and oscillatory neuron activity, and the stimuli are designed to suppress are this activity when administered to the patient. Moreover, a measuring unit records measurement signals reflecting the neuron activity of the stimulated neurons and a control and analysis unit controls the stimulation unit to administer stimuli, check the success of stimulation based on the measurement, and, if the stimulation success is not sufficient, insert one or more stimulation breaks in the application of the stimuli or extend one or more stimulation breaks, where no stimuli that could suppress the pathological synchronous and oscillatory neuron activity are applied during the stimulation breaks.

Methods of analysis to extract and assess brain data collected from subject animals, including humans, to detect intentional and unintentional brain activity and other unexpected signals are disclosed. These signals are correlated to higher cognitive brain functions or unintended, potentially adverse events, such as a stroke or seizure, and to translation of those signals into defined trigger events or tasks.

An example of a system for delivering neurostimulation energy to a patient using a plurality of electrodes may include a stimulation circuit and a sensing circuit. The stimulation circuit may be configured to deliver the neurostimulation energy using stimulation electrodes selected from the plurality of electrodes and to control the delivery of the neurostimulation energy. The sensing circuit may be configured to receive one or more neural signals from sensing electrodes selected from the plurality of electrodes and may include a signal processing circuit. The signal processing circuit may include a detection circuit and an analysis circuit. The detection circuit may be configured to detect one or more attributes of neural responses from the received one or more neural signals. The analysis circuit may be configured to analyze the detected one or more attributes of the neural responses for one or more indications of a neurodegenerative disease.

Some methods of analyzing one or more sections of a central nervous system of a patient comprise, for each of the section(s), from data the includes one or more 3D representations of the section, segmenting each of the 3D representation(s) into ventral and dorsal portions and, for at least one of the 3D representation(s), determining a mean curvature of at least a region of a surface of the dorsal portion and/or a mean curvature of at least a region of a surface of the ventral portion. Each of the section(s) can include at least a portion of a brainstem of the patient.

Methods, devices, and systems induce neuromodulation by focusing a source of stimulation through a skull/brain interface in the form of an aperture formed in the skull, a naturally occurring fenestration in the skull, or a transcranial channel. Methods, devices, and systems identify where to locate skull/brain interfaces, accessories that can be used with the interfaces, and features for controlling stimulation delivered through the interfaces. Multiple indications for the skull/brain interfaces include diagnosis and treatment of neurological disorders and conditions such as epilepsy, movement disorders, depression, Alzheimer's disease, autism, coma, and pain.

One aspect of the invention provides a method including: obtaining neural activity data for a first subject and a second subject during verbal interaction between the first subject and the second subject; and calculating coherence between the neural activity data for the first subject and the neural activity data for the second subject. Another aspect of the invention provides a non-transitory, tangible computer-readable medium comprising computer-readable program instructions for implementing the one or more of the methods described herein.

To provide a device which can diagnose a brain disease by observing a pupil diameter. A device for diagnosing a brain disease, equipped with a display image control section (3), an imaging section (5) and a judgment section (7), wherein the display image control section (3) can vary a display image displayed on a display section on the basis of a first pattern, the imaging section (5) can take an image of the pupil of a user who watches the display image, and the judgment section (7) can determine whether or not the user is affected with a brain disease using a pattern of the time-dependent change in the size of the pupil of the user which is imaged by the imaging section and the first pattern.

Described herein are biomimetic Janus particles useful as artificial antigen presenting cells capable of activating T cells in vitro. “Bull's eye” ligand patterns mimicking either the native or reverse organization of the T cell immunological synapse are provided on the surface of nano- or micro-sized particles. Methods for activating T cells in vitro using biomimetic Janus particles described herein are also provided. T cells activated by the biomimetic Janus particles can be used in adoptive immunotherapies for treating cancer, tolerance induction in autoimmune disease, autologous immune enhancement therapy, and viral infection immunotherapy. Also described herein are methods for producing a biomimetic Janus particle.