Technologies and implementations related to facilitating grouping of electrocardiogram (ECG) signals of a heart of a person (e.g., patient) wearing a wearable medical device (WMD). The ECG signals may be acquired during various times (e.g., during a normal rhythm of the heart and/or during an event of the rhythm of the heart) including various times of activity of the person (e.g., sleeping, awake, active, inactive, etc.). The ECG signals may be received and analyzed to determine if the ECG signals may be indicative of an event associated with a heart of the person or not.

In embodiments, a pre-analyzing computer receives a data record that is created by a wearable medical system (“WMS”) which may implement a wearable cardioverter defibrillator (“WCD”). The WMS has created such data records from patient data captured when the WMS has detected that the patient was having episodes of potential interest for review by clinicians. Before this review, however, the pre-analyzing computer may parse the contents of a received data record and accordingly give it a score. The score may reflect the clinician's expected preference to review this data record before or after the others. For instance, a low score may be given to data records whose contents are likely not interpretable reliably due to noise or likely of low interest after all. The pre-analyzing computer may then perform a characterizing action with reference to the data record, for facilitating the clinician to find it by its score.

A wearable medical device comprising monitoring circuitry to monitor one or more patient parameters of a patient and defibrillation circuitry to provide one or more defibrillation shocks to the patient responsive to a control signal from the monitoring circuitry. The defibrillation circuitry comprises a defibrillation capacitor to provide energy for the one or more defibrillation shocks. The wearable medical device also comprises a power source to provide power to the monitoring circuitry and the defibrillation circuitry. The power source comprises a low current power source (LCPS) to provide power to the monitoring circuitry, and a high current power source (HCPS) to provide power to the defibrillation circuitry.

Technologies and implementations for a wearable healthcare system including an information management module (IMM). The IMM may be configured to detect proximity of a healthcare device. The IMM may be configured to determine a type of the detected healthcare device. Once the type of healthcare device is determined, the IMM may be configured to communicate information regarding a medical device, where the communicated information may be adapted to correspond to the determined type of healthcare device.

In embodiments, a wearable medical system (WMS) for an ambulatory patient, which can be a wearable cardioverter defibrillator (WCD) system, analyzes the patient's ECG signal to generate a detection outcome. The WMS also has an ambulatory user interface that outputs a human-visible indication. A programming device, such as a PC, a tablet, etc., establishes a communication link with the WMS during an in-person session with the patient. The programming device may include a programming screen that reproduces the human-visible indication in real time. An advantage can be that the person programming the WMS need not strain to look also at the ambulatory user interface at the time they are looking at the programming device. Another advantage can be that the patient will recognize that he or she is better protected, and have their confidence in the WMS increased, and therefore better comply with wearing the WMS as required.

Defibrillator shock discharge control systems and schemes are described that control the shock discharge based at least in part on discharge capacitor voltage measurement taken after the defibrillation shock has been initiated.

Technologies and implementations for a wearable medical device (WMD). The technologies and implementations facilitate improved comfort and usability of WMDs. Additionally, the technologies and implementations include WMDs having wearable cardioverter defibrillator capabilities.

Disclosed herein are methods that can comprise detecting a cardiopulmonary measurement in a subject. Disclosed herein are methods that can comprise monitoring a disease in a patient by detecting a cardiopulmonary measurement. Disclosed herein are methods that can comprise treating a patient after detecting a cardiopulmonary measurement in a subject.

Percutaneous transvenous defibrillator and/or pacing devices with integrated cardiac assist devices and method of use. In some embodiments, a device may comprise a shared catheter, a defibrillator assembly, an automated external defibrillator (AED) and a cardiac assist assembly, wherein the defibrillator assembly includes at least two defibrillation coils in communication with the AED and wherein the defibrillator assembly and the cardiac assist assembly use the shared catheter for percutaneous and intravenous implantation into a patient. In some embodiments, a device may comprise a shared catheter, a pacing assembly, a pacing controller and a cardiac assist assembly, wherein the pacing assembly includes at least two electrodes in communication with the pacing controller, and wherein the pacer assembly and the cardiac assist assembly use the shared catheter for percutaneous and intravenous implantation into a patient.

A Wearable Cardioverter Defibrillator (WCD) system comprises an electrode assembly with a permeable ECG electrode and a moisture barrier. In some embodiments, the moisture barrier is configured to reduce drying out of the permeable ECG electrode to improve performance of the WCD system. In a further enhancement, some embodiments of the electrode assembly also include a pillow structure positioned on a non-skin-contacting surface of the electrode assembly to comfortably reduce movement artifact or noise in the received ECG signal.