One or more EMG sensors are configured to sense surface-EMG data indicative of muscle movement of the patient; and transmit surface-EMG data. A controller can identify at least one parameter of the surface-EMG data; compare the parameter to a corresponding dystonia-threshold-value; responsive to a determination that the parameter is greater than the corresponding dystonia-threshold-value: issue a visual-engagement command to a visual unit; and issue a tactile-engagement command to a tactile unit.

One or more EMG sensors are configured to sense surface-EMG data indicative of muscle movement of the patient; and transmit surface-EMG data. A controller can identify at least one parameter of the surface-EMG data; compare the parameter to a corresponding dystonia-threshold-value; responsive to a determination that the parameter is greater than the corresponding dystonia-threshold-value: issue a visual-engagement command to a visual unit; and issue a tactile-engagement command to a tactile unit.

Embodiments provide a wearable apparatus for acquiring electrophysiological signals of a living being. The apparatus includes a textile carrier, at least two dry electrodes attached to an inside of the textile carrier and at least two adjustable straps attached to the textile carrier that allow to adjust the wearable apparatus to a body of the living being and a contact pressure of the at least two dry electrodes to a skin of the living being.

Embodiments provide a wearable apparatus for acquiring electrophysiological signals of a living being. The apparatus includes a textile carrier, at least two dry electrodes attached to an inside of the textile carrier and at least two adjustable straps attached to the textile carrier that allow to adjust the wearable apparatus to a body of the living being and a contact pressure of the at least two dry electrodes to a skin of the living being.

A biomedical electrode of the present invention includes: a plate-shaped support portion; an elastic pillar portion that is provided on a first surface of the plate-shaped support portion; a conductive resin layer that is formed to cover a distal end of the elastic pillar portion; and a conductive wire that is electrically connected to the conductive resin layer and is arranged in the elastic pillar portion from a distal end side toward a base end side.

A biomedical electrode of the present invention includes: a plate-shaped support portion; an elastic pillar portion that is provided on a first surface of the plate-shaped support portion; a conductive resin layer that is formed to cover a distal end of the elastic pillar portion; and a conductive wire that is electrically connected to the conductive resin layer and is arranged in the elastic pillar portion from a distal end side toward a base end side.

The present invention relates to an electrode comprising a conductive pressure sensitive adhesive layer and a conductive layer. Furthermore, the invention refers to a method of manufacturing the electrode and to the use of the electrode for monitoring biosignals.

The present invention relates to an electrode comprising a conductive pressure sensitive adhesive layer and a conductive layer. Furthermore, the invention refers to a method of manufacturing the electrode and to the use of the electrode for monitoring biosignals.

A biomedical electrode includes: a plate-shaped support portion; an elastic pillar portion that is provided on a first surface of the plate-shaped support portion; and a conductive resin layer that is formed to cover a distal end of the elastic pillar portion, in which the elastic pillar portion includes a silicone rubber, the conductive resin layer includes a conductive filler and a silicone rubber, and when measured at 37° C. according to JIS K 6253 (1997), a type A durometer hardness of a surface of the elastic pillar portion is 15 or higher and 35 or lower.

A biomedical electrode includes: a plate-shaped support portion; an elastic pillar portion that is provided on a first surface of the plate-shaped support portion; and a conductive resin layer that is formed to cover a distal end of the elastic pillar portion, in which the elastic pillar portion includes a silicone rubber, the conductive resin layer includes a conductive filler and a silicone rubber, and when measured at 37° C. according to JIS K 6253 (1997), a type A durometer hardness of a surface of the elastic pillar portion is 15 or higher and 35 or lower.