The disclosure describes various aspects of an automated external defibrillator (AED) system, including shock generating electronics, a battery configured for providing power to the shock generating electronics, power management circuitry configured for managing the shock generating electronics and the battery, at least one environmental sensor configured for monitoring environmental conditions in which the AED system is placed, and a controller configured for controlling the power management circuitry and the at least one environmental sensor. The at least one environmental sensor includes a temperature sensor configured for providing a temperature measurement, and the controller is further configured for adjusting operations of the power management circuitry in accordance with the temperature measurement provided by the temperature sensor. The disclosure further describes associated methods of using the AED system.

Technologies and implementations for a wearable healthcare system including a remote device, a server, and a configurable comparator module (CCM). The CCM may be configured to facilitate communication between the server and a remote device. A wearable medical device (WMD) may be configured to provide electrocardiogram (ECG) data to the server. The CCM may be configured capture one or more portions of the ECG data to be configured and compared at the remote device. Accordingly, the CCM may be configured to display the one or more portions at the remote device capable of being utilized by a person at the remote device.

A method for a wearable cardioverter defibrillator (WCD) system comprises sensing one or more patient parameters from different parts of a body of the patient by the one or more transducers, obtaining a plurality of physiological inputs from the sensed one or more patient parameters, detecting first aspects from each of at least some of the physiological inputs, generating an aggregated first aspect from at least two of the detected first aspects, determining an aggregate analysis score from the aggregated first aspect, and determining whether the aggregate analysis score meets an aggregate shock criterion. The electrical charge is discharged within six minutes from when it is determined that the aggregate shock criterion is met, otherwise the electrical charge is not discharged for at least 19 minutes from when it is determined that the aggregate shock criterion is not met.

A variety of methods and discharge test circuits are described that are well suited for testing H-bridge based defibrillator discharge circuits. The H-bridge includes four switches and two outputs. In one aspect, a test discharge circuit is provided that includes a resistive element and a switch that are coupled to the second H-bridge output. The H-bridge and test circuit may be controlled to test various aspects of the H-bridge based defibrillator discharge circuit.

The disclosure describes various aspects of an automated external defibrillator (AED) system, including shock generating electronics, a battery configured for providing power to the shock generating electronics, power management circuitry configured for managing the shock generating electronics and the battery, at least one environmental sensor configured for monitoring environmental conditions in which the AED system is placed, and a controller configured for controlling the power management circuitry and the at least one environmental sensor. The at least one environmental sensor includes a temperature sensor configured for providing a temperature measurement, and the controller is further configured for adjusting operations of the power management circuitry in accordance with the temperature measurement provided by the temperature sensor. The disclosure further describes associated methods of using the AED system.

A remote monitoring device and related systems and methods for monitoring and managing by a monitoring service via a communications network a condition of an AED based on audio signals from the AED. The remote monitoring device includes a housing configured to be positioned outside of the AED such that audio sounds from the AED can be detected. The housing contains at least one processor, a communications module, a first audio sensor, a first audio detection circuitry, a second audio sensor, and a second audio detection circuitry. The communications module is operably connected to the at least one processor and configured to transmit electronic communications to the monitoring service via the communications network. The at least one processor is configured to power on in response to the wakeup notification signal, process digital audio signals, and transmit a signal to the monitoring service to report a condition of the AED.

An external wearable medical device includes a plurality of electrocardiogram (ECG) sensors, at least one accelerometer configured to be disposed on a patient, and at least one processor operatively coupled plurality of ECG sensors and the at least one accelerometer. The at least one processor is configured to receive an ECG signal from the plurality of ECG sensors, receive patient activity data from the at least one accelerometer, and detect, based on the patient activity data from the at least one accelerometer, data indicative of an impending syncope event. The at least one processor is configured to issue a notification of the impending syncope event, and store in a memory during a first time period data comprising the ECG signal in association with information descriptive of impending syncope event, and transmit to a remote server during a second time period the stored data for analysis at the remote server.

Status messages are wirelessly broadcast from medical devices (e.g., defibrillators) as advertisements that don't require the establishment of a wireless connection with listeners. The listeners are configured to act on, or forward, received status messages as appropriate. The listeners may optionally include supplemental information supplied by the listener when forwarding a status message to a management server. The listener may optionally analyze received status messages to determine whether an action should be taken based at least in part on status information in the message. Actions performed by the listener may include initiating a connection with the transmitting device to facilitate uploading new information from the medical device, updating the medical device's firmware, etc. Optionally, some of the advertisements are configured as beacons. The advertisements/beacons may be transmitted using a Bluetooth Low Energy or other suitable protocols. In another aspect, advertisement based arrangements for spreading responder network incident alerts are described.

An apparatus may be configured for providing feedback to caregivers during a code blue scenario when adhered to the chest of a subject undergoing resuscitation by sensing and transmitting information associated with the code blue scenario. Such information may include one or more of vital signs of the subject during resuscitation, information associated with chest movements of the subject during resuscitation, and audio information from an environment of the subject during resuscitation. One or more processors may generate real-time feedback for communication to the caregivers during the code blue scenario based on the sensed and transmitted information.

The present disclosure provides systems and methods for protection circuitry for an implantable pulse generator (IPG) of a neurostimulation system. The protection circuitry is coupled to an IPG ground, a plurality of electrodes, and an IPG case, and operable to protect IPG stimulation and sensing circuitry from damage during electrostatic discharge and cardiac defibrillation, and to mitigate unintended stimulation during electromagnetic interference. The protection circuitry includes an IPG ground connection, a plurality of protection Zener diodes, wherein one of the protection Zener diodes is electrically coupled between the IPG case and a float Zener diode, and wherein the remaining protection Zener diodes are electrically coupled between the plurality of electrodes and the float Zener diode, and the float Zener diode electrically coupled between the plurality of protection Zener diodes and the IPG ground.