An electrode for acquiring electroencephalogram signals of a user includes a base and a plurality of legs extending from the base at first extremity. The legs include a second extremity covered with an electrically conductive material. The second extremity includes a smaller cross-section than the first extremity of the legs so the legs can penetrate through hair of the user. The legs elastically flex such that, when the electrode is applied on a user's head, the electrically conductive material of the second extremity contacts a scalp of the user, wherein the base is of cuboid shape having two side faces, the legs being directly attached to the side faces of the base, the legs being symmetrically attached to the base with respect to a longitudinal axis and the legs attached to a side face of the base facing the legs attached to the other side face of the base.

A method of automatically monitoring electrophysiological data in the brain and detecting clinically significant events comprises receiving signal inputs from at least one or more electrophysiological signal channels each indicative of electrical brain activity. For each of the one or more electrophysiological signal channels, the signals are filtered to obtain a first subchannel having a first frequency range and a second subchannel having a second frequency range. Appearance of a succession of correlated, non-synchronous events are detected in the waveforms of the one or more first subchannels to create a first detection output. Suppression of an amplitude of the signal is detected in one or more of the second subchannels correlated with the detected events in the one or more first subchannels to create a second detection output. The detected events are classified as a predetermined type of clinically significant event according to the first and second detection outputs. Spreading depolarization waves, peri-infarct depolarizations and other clinically significant events may be classified and displayed.

Modular physiological sensors that are physically and/or electrically configured to share a measurement site for the comfort of the patient and/or to ensure proper operation of the sensors without interference from the other sensors. The modular aspect is realized by providing outer housing shapes that generally conform to other physiological sensors; mounting areas for attachment of one sensor to another sensor; providing release liners on the overlapping sensor attachment areas; and/or providing notches, tabs or other mechanical features that provide for the proper placement and interaction of the sensors.

Pulse waves and ballistocardiac waves propagate to a piezoelectric vibration sensor 110 attached to a seating surface 102 of a chair 100, and are output after being converted to electrical signals. Thereafter, the electrical signals are filtered by a low-pass digital filter 202P and a band-pass digital filter 202B, with the pulse waves GP output from the low-pass digital filters 202P and the ballistocardiac waves GB output from the band-pass digital filter 202B. These pulse waves GP and ballistocardiac waves GB are processed by absolute value circuits 212P, 212B and low-pass filters 214P, 214B of envelope-processing circuits 210P, 210B, to obtain envelopes. Then, pulse wave propagation velocity PWV is calculated based on the difference between the peaks of the obtained envelopes. The pulse waves/their velocity can be detected/obtained even when the piezoelectric vibration sensor is not attached directly to the human body.

The object is to acquire electroencephalogram of high resolution with fewer number of electrodes than usual. An electroencephalogram measurement apparatus comprising: a plurality of electrodes 110 attached on the scalp of a subject for acquisition of electroencephalogram signals of the subject; and an electroencephalogram generation unit 150 for generating an electroencephalograms at locations of the scalp where the electrodes are attached and electroencephalograms at locations of the scalp where the electrodes are not attached.

Disclosed is an audio-headset for acquisition of a bio-signal from a subject, including a first earpiece; a second earpiece; an arch connecting the first earpiece and the second earpiece; the arch including a hub (4); wherein the arch, the first earpiece and the second earpiece are configured so that the earpieces are placed over a subject's ears when the audio headset is worn by the subject; and at least one posterior branch (1) having a first end extending from the hub and a second free end; the at least one posterior branch (1) including a concave surface with a radius of curvature, a collapsed state when the headset is not worn by the subject and an expanded state when the headset is worn by the subject.

Provided is a biological electrode tool including an electrode portion (10) attached to a human body to acquire a biological signal, and a lead portion (20) for externally leading out the biological signal from the electrode portion (10). The entire areas of the upper and lower surfaces of the electrode portion (10) are covered with a nonwoven fabric (30) except for a portion that contacts the living body (13). The entire areas of the upper and lower surfaces of the lead portion (20) are also covered with nonwoven fabric except for an external lead-out end portion (14). The full circumferential peripheries of the nonwoven fabrics (30) on the upper and lower surfaces of the electrode portion (10) and the lead portion (20) are bonded except for the portion that contacts the living body (13) and the external lead-out end portion (14). Neither the electrode (11) of the electrode portion (10) nor a thin-film lead wire (21) of the lead portion (20) are exposed.

A wearable electrode includes: a garment including an outer member and a backing member configured to cover at least a part of an inner surface of the outer member; and an electrode unit configured to come into contact with a living body clothed in the garment to acquire a biological signal emitted by the living body and attached to an opposite side of the backing member from the outer member, and a core wire which can be inserted into an accommodation section formed in the electrode unit. The outer member and the backing member are connected to a part other than a part of the backing member, to which the electrode unit is attached.

A system for closed-loop pulsed transcranial stimulation for cognitive enhancement. During operation, the system identifies a region of interest (ROI) in a subject's brain and then estimates ROI source activations based on the estimated source of the ROI. It is then determined if a subject is in a bad encoding state based on the ROI source activations. Finally, one or more electrodes are activated to apply a pulsed transcranial stimulation (tPS) therapy when the subject is in a bad encoding state, a predefined external event or behavior occurs, or the subject is in a consolidation state during sleep.

An ear tip for an earpiece including a body having first and second ends, an inner wall extending between the first and second ends to define a hollow passage to conduct sound waves, and an outer wall connected to the inner wall of the body at the first end and tapering away from the inner wall toward the second end. The ear tip further includes first and second electrically conductive elements arranged on an outer surface of the deformable outer wall.