Various embodiments are directed to signal processing. In accordance with example embodiments, methods and apparatuses involve using at least two electrodes that sense an ECG signal. A denoising module is communicatively coupled to the at least two electrodes, and receives the ECG signal sensed by the sensing electrodes. The denoising module includes circuitry that conditions and digitizes the ECG signal, and a computing circuit that processes the digitized ECG signal to denoise the ECG signal. A communications circuit generates a communication including the denoised ECG signal for access by a remote device.

A method of modifying contact status of one or more electrodes in a plurality of electrodes located on a medical device includes measuring an electrical characteristic of each electrode in the plurality of electrodes located on the medical device, determining a contact status for each electrode in the plurality of electrodes based on the measured electrical characteristic for the corresponding electrode, wherein the contact status is indicative of contact with adjacent tissue. The method further includes modifying the contact status of a first electrode in the plurality of electrodes based on the determined contact status of one or more other electrodes in the plurality of electrodes.

The present invention relates to a physiological measurement device (11) comprising a processor (37) configured to input (47, 49) at least one digital signal (x) from frontend circuitry (17) of the measurement device (13), the digital signal (x) representing an analog signal (s) present at an input (13) of the frontend circuitry (17) and at least one filtered digital signal (y), the filtered digital signal (y) generated by at least one digital filter (27) from the digital signal (x) based on a set of filter coefficients (f.sub.k). In order to allow for implementing alarm-related monitoring efficiently in terms of cost and power consumption so that interference with other measurements devices applied to the same patient is minimized, it is proposed that the measurement device (11) comprise a coefficient calculator (31) configured to perform an adaptation operation (51) based on the digital signal (x) and the filtered digital signal (y); and a checker (33) configured to determine (53) alarm information (A) from a result (f.sub.k, g.sub.1) of the adaptation operation (51).

A medical patch includes a substrate, an electrode, and circuitry. The substrate is configured to attach externally to a patient. The electrode is coupled to the substrate and is configured to sense electrocardiogram (ECG) signals from a heart of the patient, and to further sense electrical signals indicative of an impedance between the electrode and a probe in the heart. The circuitry is coupled to the substrate and includes a shared amplifier that is configured to simultaneously amplify the ECG signals and the electrical signals sensed by the electrode.

A medical patch includes a substrate, an electrode, and circuitry. The substrate is configured to attach externally to a patient. The electrode is coupled to the substrate and is configured to sense electrocardiogram (ECG) signals from a heart of the patient, and to further sense electrical signals indicative of an impedance between the electrode and a probe in the heart. The circuitry is coupled to the substrate and includes a shared amplifier that is configured to simultaneously amplify the ECG signals and the electrical signals sensed by the electrode.

Electrodes for use in electroencephalographic recording, including consciousness and seizure monitoring applications, have novel features that speed, facilitate or enforce proper placement of the electrodes, including aligning tabs and arrowed aligning juts, color coding, and an insulating bridge between reference and ground electrodes which ensures a safe application distance between the conductive regions of the two electrodes in the event of cardiac defibrillation or to prevent shorting between the adjacent electrodes by preventing the conductive path to be shared. A method of using a set of four such electrodes is also disclosed.

The present invention provides a medical electrode comprising a conductive metal base comprising a plate element and a boss formed on the plate element and a conductive support cylinder separate from the conductive metal base. The conductive support cylinder is rotatably mounted to the conductive metal base while remaining in electrical communication with said conductive metal base. The present invention also provides a limb clamp for an ECG device. According to the present invention, it is possible to prevent bending of the cable connecting with the medical electrode, thereby avoiding cable failure.

An apparatus includes: a first layer including first and second measurement electrodes disposed at a distance from one another, wherein the first and second measurement electrodes are skin electrodes that measure an electric physiological property from a skin; and a second layer disposed on top of the first layer including first and a second shielding elements that are electrically conductive and arranged to cover at least partially both the first and second measurement electrodes to protect the first and second measurement electrode against electromagnetic interference. Each of the shielding elements are connected to a skin electrode. The first shielding element and the second shielding element extend adjacent with respect to one another between the first and second measurement electrodes on a plane defined by the second layer. The second shielding element is electrically isolated from the first shielding element.

A system includes a conformable biopotential sensor that withstands a defibrillation pulse. The conformable biopotential sensor includes a polymer substrate, a plurality of electrodes printed on the polymer substrate, a signal trace printed on the polymer substrate, and one or more resistors printed on the polymer substrate and in electrical communication with an electrode of the plurality of electrodes via the signal trace. One or both of the one or more resistors and the polymer substrate withstand a defibrillation pulse. The conformable biopotential sensor further includes a coating layer applied to the one of both of the one or more resistors, wherein the coating is more thermally conductive than the polymer substrate.

A catheter system includes a mapping catheter including a plurality of mapping electrodes, each mapping electrode configured to sense signals associated with an anatomical structure. The catheter system further includes a processor operatively coupled to the plurality of mapping electrodes and configured to receive the signals sensed by the plurality of mapping electrodes, characterize the signals sensed by the plurality of mapping electrodes based on a signal parameter of the sensed signals, and generate an output of a quality of contact of the plurality of mapping electrodes with the anatomical structure based on the signal characterization.