Methods and devices for correcting electrocardiogram (EKG) indication saturation may include receiving an EKG indication from at least one sensor and determining that a saturation condition has been met in response to receiving the EKG indication. Additionally, the methods and devices may include incrementing an EKG saturation level based on a determination that the saturation condition has been met. Moreover, the methods and devices may include determining whether the EKG saturation level satisfies an EKG saturation threshold. The methods and device may include disregarding at least a second EKG indication in accordance with a determination that the saturation level satisfies the EKG saturation threshold. The methods and devices may further include transmitting the second EKG indication to an output device in accordance with a determination that the saturation level does not satisfy the EKG saturation threshold.

A patient monitoring system includes a capacitive electrode connectable to a patient to detect an output signal and a signal generator unit that transmits a carrier signal to the capacitive electrode, the carrier signal having a carrier frequency and a carrier amplitude. The patient monitoring system further includes an amplifier unit that amplifies the output signal detected by the capacitive electrode to generate an amplified output signal. A gain determination module in the patient monitoring system determines an output amplitude of a carrier frequency portion of the amplified output signal, and determines a system gain based on a comparison between the output amplitude and the carrier amplitude. A voltage determination module in the patient monitoring system filters the output signal to isolate a physiological signal detected from the patient, and determines a voltage of the physiological signal based on the system gain.

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.

A device for detecting, monitoring and optionally recording ECG signals is disclosed. The device has at least two electrodes and an on-board memory. The electrodes can be recoatable and/or replaceable. The device can be charged wirelessly through the electrodes or by an internal energy harvesting system. A power saving mode is provided whereby the electrodes are activated by a pre-defined tapping pattern of electrical contact applied by a user and, upon activation, the device starts pairing with and transmitting ECG signals to a receiving station, e.g. a computer, a smart phone, a tablet or the like.

A method is for determining electrode status information relating to an electrode in a differential voltage measuring system for measuring a bioelectric signal, the electrode status information indicating whether the electrode is connected or not connected. An embodiment of the method includes the acquisition of a temporal profile of an electric current flowing through a shunt resistor, wherein the shunt resistor is arranged in series with the electrode in an electric transmission path of the differential voltage measuring system, and the determination of the electrode status information on the basis of the temporal profile.

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.

A medical device system and method for detecting dislodgement of a lead determines one or more characteristics of a cardiac signal received via the lead that are associated with dislodgement of the lead during atrial fibrillation, and detects dislodgement of the ventricular lead based on the determined characteristics. The medical device and system provides a lead dislodgment alert in response to detecting dislodgement. In some examples, an implantable medical device withholds delivery of a defibrillation therapy based on detecting dislodgement of the lead.

A system is provided for testing the electrical integrity of an implanted pacemaker or defibrillator lead. The system includes a container holding an electrically conductive solution, such as a saline solution. A voltage source and two electrodes are provided to pass an electrical current through the solution. To use the system, the proximal end of the electrical lead is disconnected from the implanted electronic device, passed through the saline solution and then electrically connected to a device/monitor. During testing, the device/monitor sends a test pulse through the lead and monitors electrical activity in the lead. To test sequential locations along the length of the proximal segment, the segment is drawn through the saline solution and between the electrodes while test pulses are sent and monitored. The monitor detects abnormal electrical activity in the lead indicative of a break in lead insulation.

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.

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.