Cardiac electrodes and techniques for testing application of the electrodes to a victim are described herein.

An automated external defibrillator includes a first pad at least partially colored in a first color, a second pad at least partially colored in a second color, and a main unit to which the first pad and the second pad are connected. The main unit has a first guidance surface that indicates how to attach of the first pad and the second pad. The first guidance surface has a first marker in the first color at a position corresponding to an attachment position of the first pad and a second marker in the second color at a position corresponding to an attachment position of the second pad.

A defibrillation pad for a defibrillator, includes: a pair of electrode pads (10) each including a gel portion (12); lead wires (21, 22); a pair of nonconductive release liners (30A, 30B) each detachably stuck to the corresponding gel portion (12) and each having a through hole (32A, 32B) opposed to the corresponding gel portion; and a connecting member (40) comprising an electric connecting pattern (41) having a predetermined electrical resistance, wherein the pair of gel portions (12), each of which is exposed from the corresponding through hole (32A, 32B), are electrically connected to each other through the electric connecting pattern (41) in a state where each of the pair of release liners (30A, 30B) are stuck to the corresponding gel portion. The connecting member (40) has a cut region (45) by which the pair of gel portions are electrically disconnected to each other when the pair of electrode pads are stuck to a living body.

An external defibrillator system is provided. The system includes: a graphical display; one or more sensors for obtaining data regarding chest compressions performed on a patient; and a controller configured to display on the graphical display numeric values for depth and/or rate of the chest compressions based upon the data from the one or more sensors. A method for using an external defibrillator including the steps of: obtaining data regarding chest compressions performed on a patient; and displaying on a graphical display screen of the defibrillator numeric values for depth and/or rate of the chest compressions based upon the data is also provided.

A method of treating a waste evacuation dysfunction comprising administering transcutaneous electrical stimulation (TES) to at least one lower pelvic and/or sacral region for a specific treatment regimens. Also disclosed is a system for configuring a stimulation device to deliver transcutaneous electrical stimulation (TES) the system comprising: a computing device storing or having access to a plurality or TES settings and comprising a user interface to enable authorized selection of at least on of the TES settings for provision of TES by the stimulation device according to the at least one selected TES setting and the stimulation device communicatively coupled to the computing device to receive and store the selected at least one TES setting the stimulation device being of a size to be readily carried on a body and configured to selectively provide current to external electrode according to the one TES setting.

Embodiments of a wearable device are provided. The wearable device comprises a reusable component and a disposable component. The disposable component comprises a patient engagement substrate comprising adhesive on a bottom side, an electrode on the bottom side, a disposable component electrical connector, and a disposable component mechanical connector. The reusable component comprises a plurality of sealed housings mechanically coupled to each other and movable with respect to each other, each of the plurality of housings containing one or more of a capacitor and a controller, a reusable component mechanical connector adapted to removably connect to the disposable component mechanical connector, and a reusable component electrical connector adapted to removably connect to the disposable component electrical connector. The device can comprise a cardiopulmonary physiologic monitor or an automatic external defibrillator, among other types of devices.

The present invention relates to electrocardiography and to electrode arrangements used in electrocardiographic monitoring devices, and is more particularly related to a pad or patch containing said electrodes which may be used to passively and non-invasively monitor electrical activity generated by a patient's heart from the surface of that patient's chest, and to a connector which allows for fast and simple connection between the pad containing said electrodes and the devices and equipment typically used to monitor and view electrocardiographic information.

A lower body electrical muscle stimulation exercise system for exercising the legs of a paralyzed user which incorporates electrical stimulation of leg muscles. The device is portable, light-weight and functional. The device is placed in front of a user who is sitting in a chair. The user's legs may be placed on moveable leg supports. An electric motor rotates a bicycle crank assembly which moves the legs of a user in a back and forth bending motion. Electrical stimulation is then activated which contracts or relaxes the leg muscles. The stimulation is sequentially activated by a Master Processor and a Transcutaneous Electrical Nerve Stimulator (TENS) unit. The present invention is designed to stop the deterioration of the leg muscles and restore the functionality of the legs.

An electrode for electrostimulation includes an electric path having a storage structure for an electrolyte which comprises a front side for placing the electrode onto the skin of a living being and a rear side for making electric contact, at least one electrically conductive contacting structure, and an electric pad comprising at least one barrier structure for preventing a lateral flow of electrolytes.

Articles and methods of making articles are described. In one embodiment, an electrode is described, comprising an ionically-conductive hydrogel layer comprising a first major surface and opposing major surface. The electrode further comprises a discontinuous primer layer disposed on the first major surface ionically-conducting hydrogel layer and an electrically conductive member or a connector component thereof, in contact with the first major surface of the ionically-conducting hydrogel layer. In another embodiment, an article is described comprising a hydrogel layer comprising a first major surface and opposing major surface; a discontinuous hydrophobic primer layer disposed on the first hydrogel layer; and a hydrophobic adhesive or hydrophobic backing bonded to the primer and discontinuous hydrophobic primer layer of the hydrogel.