Systems and methods for applying and/or receiving electrical, magnetic, magnetoelectric, vibratory, or electromagnetic signals to biological tissues are described. In some embodiments, a system including a body and an electrode may be placed in contact with a biological tissue portion. A force may be applied to the body such that the body plastically deforms to adapt to a shape of the biological tissue portion, and the electrode may be used to apply and/or receive an electrical signal via the biological tissue portion.

An electrode assembly includes a first surface to be placed adjacent a person's skin and a second surface including a plurality of reservoirs of conductive gel. The plurality of reservoirs of conductive gel are disposed on sections of the electrode assembly that are at least partially physically separated and may move at least partially independently of one another to conform to contours of a body of a patient. The electrode assembly is configured to dispense an amount of the electrically conductive gel onto the first surface in response to an activation signal and to provide for a defibrillating shock to be applied to the patient through the amount of the electrically conductive gel.

A system and method for identifying a stimulation location on a nerve is disclosed. The system includes an image-based navigation interface used to facilitate advancing a stimulation element within a patient body toward a target nerve stimulation site. Using the system one determines, separately for each potential target nerve stimulation site, a neuromuscular response of muscles produced upon applying a stimulation signal at the respective separate potential target stimulation sites. The image-based navigation interface is configured to display a graphic identification of which muscles were activated for each respective potential target nerve stimulation site upon applying the stimulation signal.

Non-adhesive medical attachment articles include a first rotationally distinct segment (110), where the first rotational segment has a circular or semi-circular array of angled microneedles (111), and a second rotationally distinct segment, (120) with a second sequential circular or semi-circular array of angled microneedles (121). A communication member (130) connects the two rotationally distinct segments. The arrays of microneedles are angled in opposite directions, and the segments rotate in opposite directions.

Disclosed is a sensor for measuring skin conductivity and a method of manufacturing the same, wherein the sensor includes: a base board made of a flexible material; an electrode provided on a surface of the base board, and transmitting an electrical signal; and an uneven structure provided on the electrode, and configured to increase an electrical contact area with skin via sweat secreted onto a surface of skin.

An electrode device for measuring a living body is herein disclosed. The electrode device for measuring a living body signal includes a body comprising a handle part and a tongs part, the body elastically moving by an external force, an electrode part comprising needles disposed on inner surfaces of the tongs part to face each other, and a wire part connected to one end of the electrode part for a connection with a measuring device.

An electrode assembly includes a first surface to be placed adjacent a person's skin and a second surface including a plurality of reservoirs of conductive gel. The plurality of reservoirs of conductive gel are disposed on sections of the electrode assembly that are at least partially physically separated and may move at least partially independently of one another to conform to contours of a body of a patient. The electrode assembly is configured to dispense an amount of the electrically conductive gel onto the first surface in response to an activation signal and to provide for a defibrillating shock to be applied to the patient through the amount of the electrically conductive gel.

An EEG headpiece includes an array of electrode pins, each electrode pin extending between a proximal end, formed by a proximal end face, and a distal end and including a conducting electrode and a thermoplastic material. The thermoplastic material is arranged at least around a periphery of the electrode pin or is pressable from a hollow space to the periphery. Each electrode pin is equipped for the transmission of energy, especially mechanical vibration energy, from the proximal end face to the thermoplastic material to liquefy at least portions of the thermoplastic material from a solid state to a flowable state, whereby the thermoplastic material is capable of flowing into structures of a tissue portion surrounding the periphery and of forming, after re-solidification of the thermoplastic material, an anchoring of the electrode pin in the tissue portion.

This invention is directed to materials and devices for sensing bio-potential signals from animals, particularly to sensing bio-potential signals to monitor humans in the medical field. In general, bio-potential sensors may be attached to the body of an animal, such as a human, in order to receive bio-potential signals such that information about the bioelectrical properties of the cells and/or tissues of the animal may be gathered. The bio-potential sensor may generally include a dry electrode that may be placed in contact with the skin of an animal to receive bio-potential signals from the animal. A dry electrode may generally include an electrically conductive solid material which may conduct electrical signals from an animal.

A method is provided for manipulating target tissue of a patient during a medical procedure. The method includes introducing a medical instrument system to a general site of target tissue. At least one characteristic of the target tissue is identified using an imaging device located in a working channel of the medical instrument system. The imaging device is removed from the working channel of the medical instrument system, and a medical instrument is inserted through the working channel of the medical instrument system. The target tissue is then manipulated using the medical instrument. A medical instrument system is also provided for manipulating target tissue of a patient during a medical procedure.