A biosensor, which operates by power supplied from a battery, includes an electrode portion positioned on at least a side of one terminal of the battery; and a conductive adhesive tape having conductivity provided between the one terminal and the electrode portion. A fluctuation width of a resistance value of the conductive adhesive tape is 1.60Ω or less in absolute value when an iron ball having a weight of 33 g is dropped vertically from a height of 30 cm to apply a load to a surface of the conductive adhesive tape.

In one embodiment, an ECG monitoring system includes two or more electrodes configured to record cardiac potentials from a patient, at least one processor, and a rapid acquisition module executable on the at least one processor to: determine that an impedance of each electrode is less than an impedance threshold; record initial ECG lead data based on the cardiac potentials; determine that a noise level in each ECG lead of the initial ECG data is less than a noise threshold; start a recording timer once the noise level is below the noise threshold; record an ECG dataset while the noise level is maintained below the noise threshold until the recording timer reaches a predetermined test duration; store the ECG dataset and provide a completion alert.

Method and system for monitoring an internal electrical impedance of a biological object including Internal Thoracic Impedance (ITI) comprising placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise three equally spaced electrodes; imposing an alternating electrical current between pairs of the electrodes and obtaining voltage signals representative of a voltage drop thereon, calculating two values of internal electrical impedance of the biological object corresponding to the uttermost electrodes of said two arrays of electrodes placed on the opposite sides of the biological object.

Wearable physical health testing systems and associated devices and methods are disclosed herein. A wearable system configured in accordance with embodiments of the present technology can include, for example, a communications hub, and a plurality of physical health testing devices. The communications hub and the plurality of physical health testing devices can integrated into an article of clothing, such as a jacket, a shirt, or a body suit. The physical health testing devices are in wired and/or wireless communication with the communications hub. Each physical health testing device is configured to generate physical health data of a user and to transmit generated physical health data to the communication hub and/or a user's mobile device. The wearable system provides an automated physical exam that can be performed at user's homes or other convenient locations.

Wearable physical health testing systems and associated devices and methods are disclosed herein. A wearable system configured in accordance with embodiments of the present technology can include, for example, a communications hub, and a plurality of physical health testing devices. The communications hub and the plurality of physical health testing devices can integrated into an article of clothing, such as a jacket, a shirt, or a body suit. The physical health testing devices are in wired and/or wireless communication with the communications hub. Each physical health testing device is configured to generate physical health data of a user and to transmit generated physical health data to the communication hub and/or a user's mobile device. The wearable system provides an automated physical exam that can be performed at user's homes or other convenient locations.

An ECG monitoring method and apparatus are presented in which contact impedances including capacitive components are utilized to, for example, reduce false alarms for lead-off conditions. In one aspect of the disclosure a method includes monitoring a plurality of Electrocardiogram (“ECG”) electrodes ostensibly electrically connected to a human body; determining the respective contact impedance for each of the ECG electrodes as a plurality of electrical currents is driven through the ECG electrodes in a predetermined pattern, each respective contact impedance including a resistive component and a capacitive component; ascertaining whether any of the determined respective contact impedances exceeds a predetermined threshold; if any of the determined respective contact impedances exceeds the predetermined threshold, issuing an alarm.

The invention relates to a method and apparatus for diagnosis of conductor anomalies, such as insulation failures, in an implantable medical device, such as an implantable cardioverter defibrillator (ICD), a pacemaker, or a neurostimulator. Insulation failures are detected and localized by identifying changes in electrical fields via surface (skin) potentials. Small variations in potential are detected along the course of the electrode near the site of insulation failure.

A wearable electronic device and method are disclosed, including: at least one sensor including a plurality of electrodes, at least one processor operatively connected with the at least one sensor, and a memory operatively connected with the at least one processor. The processor implements the method, including detecting coupling of the wearable electronic device with an external accessory contacting a body of a user, and based on detecting the coupling with the external accessory, measuring a biometric signal using a voltage received from at least two electrodes from among a plurality of measurement electrodes included in the external accessory.

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

A lightweight, disposable and substantially radiolucent electrode or sensor assembly for that universally connects to separate, non-integrated electrodes or sensors for the monitoring of the physiological parameters of a live subject wherein the electrode assembly is comprised of one or more radiolucent electrical connectors for connecting the electrode assembly to the sensors. The present invention also discloses a method of positioning the electrode assembly on a patient whose physiological signs are being monitored such that access to the patient's chest is substantially unimpeded so as not to obstruct the electromagnetic imaging of the patient's chest, the application of defibrillation paddles or surgical procedures that require access to the chest area.