Certain examples of the present invention relate to a multi-electrode device for use with a user's body part. Certain examples provide an apparatus (100) comprising: a plurality of electrodes (101); a signal line (102) for conveying electrical signals to or from the plurality of electrodes (101); wherein the plurality of electrodes (101) and the signal line (102) are integrally formed in the apparatus (100), and wherein the apparatus (100) is configured such that a user is able to selectively electrically couple one or more of the plurality of electrodes (101) to the signal line (102).

An apparatus includes a controllable signal source and a processor. The controllable signal source is configured to apply an Alternating Current (AC) signal to multiple electrodes of a multi-electrode catheter immersed in an aquatic solution. The processor is configured to, responsively to the applied AC signal, estimate a respective surface impedance or a respective electrical noise level of each of the electrodes. The processor is further configured to disconnect each electrode, independently of other electrodes, when the estimated surface impedance or electrical noise level of the electrode drops below a preset value.

An apparatus includes a controllable signal source and a processor. The controllable signal source is configured to apply an Alternating Current (AC) signal to multiple electrodes of a multi-electrode catheter immersed in an aquatic solution. The processor is configured to, responsively to the applied AC signal, estimate a respective surface impedance or a respective electrical noise level of each of the electrodes. The processor is further configured to disconnect each electrode, independently of other electrodes, when the estimated surface impedance or electrical noise level of the electrode drops below a preset value.

The present invention relates to a switchable filter device for use in a system for recording electro-physiological signals. The filter device comprises a plurality of recording channels, the recording channels comprising an ablation recording channel. Each recording channel has a patient side terminal at a patient interface and a corresponding recording side terminal at a recording device interface. Each recording channel comprises a first signal path with a first frequency dependent transmission characteristic having a first pass band, a second signal path with a second frequency dependent transmission characteristic different from the first frequency dependent transmission characteristic, the second frequency dependent transmission characteristic having a second pass band overlapping the first pass band, and switching devices operable to switch between the first signal path and the second signal path in response to a control signal indicative of a transient interference signal. Preferably, switching from the second signal path to the first signal path is performed with a switching delay after termination of the transient interference signal.

The invention relates to a system for measuring, classifying and displaying electrical cardiac activity, characterized in that it comprises a device for acquiring, processing and conditioning electrical cardiac signals, which is formed by: a signal acquisition module comprising more than two sensors for measuring electrical cardiac activity, the sensors being designed to be put on the phalanges of the fingers of a user's hand to measure cardiac electrical activity; a signal-conditioning module; a processing and logical control module; a module for feeding back to the user; a connectivity module; and a power source module, wherein the apparatus is configured to connect to a local network that includes any technological assembly such as smartphones, tablets and computers, with the possibility of connecting to the Internet or at least to a server/client with the ability to store and process information and optimize operational algorithms of the apparatus, the apparatus being integrated in such a way that it can be carried and used in the user's hand.

Multiple circuits in a computing device can share one or more conductive elements. The use of the conductive element can vary by circuit, such as an antenna radiator for a radio frequency (RF) circuit or an electrode for an electrocardiography (ECG) circuit. The circuitry sharing a conductive element can utilize signals obtained over different frequency ranges. Those ranges can be used to select decoupling circuitry, or elements, that can enable the respective circuits to obtain signals over a respective frequency range, excluding signals over one or more other frequency ranges corresponding to other circuitry sharing the circuit. Such an approach allows for concurrent independent operation of the circuitry sharing a conductive element.

A method is disclosed comprising: performing a first scan of an organ using a set of electrodes in a catheter that are currently active; deactivating one or more of the electrodes in the set based on data that is collected as a result of the first scan; tuning the set by at least one of (i) deactivating one or more electrodes in the set that remain active after the deactivating, and (ii) activating one or more electrodes in the catheter that are inactive; performing a second scan of the organ using electrodes in the set that are currently active after the tuning is performed, and generating a map of the organ based on data collected as a result of the second scan; and outputting the map of the organ for presentation to a user.

A physiological data acquisition system includes at least one interface module and a base unit configured to communicatively connect to the at least one interface module to receive the physiological signals recorded by a catheter. Each interface module is formed by mating at least a first one of the two or more different personality modules to a dock. The dock has a multi-modal connection port configured to directly connect to a dock connector of any one of the two or more different personality modules so as to receive physiological signals therefrom. The first personality module includes a first catheter connector configured to receive a connection end of the catheter so as to receive physiological signals therefrom, and a first dock connector configured to connect to the multi-modal connection port of the dock so as to provide the physiological signals thereto.

An electronic device includes a multiplexer (MUX), a switching array and logic circuitry. The MUX includes multiple input ports and an output port, and is configured to receive, via the input ports, multiple input signals, and to output, via the output port, a selected signal among the input signals. The switching array is coupled to the input ports of the MUX and is configured to receive the input signals and to connect or disconnect between each input signal and a respective input port. The logic circuitry is electrically coupled to the switching array and to the MUX, and is configured to control the switching array to connect at least the selected signal that the MUX is outputting, and to disconnect all the input signals other than the at least selected signal.

An electrophysiology data acquisition system that receives physiological signals from at least one catheter includes an amplifier and at least one noise reduction circuit operatively connected to the amplifier and configured to cancel interference in the physiological signals from the catheter. A drive selection circuit is controllable to connect any one of two or more available electrodes to the noise reduction circuit such that the connected electrode becomes an equalization drive electrode for the catheter. An equalization control module is executable on a processor and configured to select the equalization drive electrode from the two or more available electrodes and to control the drive selection circuit to connect the selected equalization drive electrode to the noise reduction circuit.