An automated wearable belt cardiac defibrillator (BCD) for wearing by a subject, comprising: at least two patches adapted for adhering to the subject each comprising a defibrillation electrode and an ECG sensor; and a BCD controller connected to each of the patches, wherein the patches comprise an adhesive adapted for long-term adhering of the patches to the subject, wherein the adhesive is a biocompatible adhesive, wherein the patches and adhesive are adapted for movement of the subject while the patches are adhered to the subject, wherein the patches are replaceable, wherein the controller is housed in a belt for wearing by the subject, wherein the belt is adapted for being flexible, wherein the adaptation for being flexible comprises a plurality of compartments for housing components of the controller, wherein a method for usage of the BCD comprises: following completion of an operational period, positioning of the patches to alternative locations on the subject wherein each of the alternate locations represents an alternate shock vector.

Disclosed are a timeline-based navigation feature and a channel selection feature. The timeline-based navigation feature allows the user to visually identify significant events during an episode and quickly navigate the display of data to those significant events. Embodiments of such feature allow a user to quickly see that there is a shock delivered, for example, and click on that part of a timeline navigator to advance the detailed display of data to that point in the episode. The data channel selection feature enables selection of display channel(s) from among a set of available data channels. Embodiments of such feature enable a selection and/or deselection of various channels for display to minimize display of extraneous data and/or to select preferred channels of data for review.

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.

Various techniques related to post-treatment parameters of patients are described. An example method includes identifying a segment of an electrocardiogram (ECG) of an individual, wherein the segment is detected during a time interval that begins when an electrical shock is output to the individual's heart. The method further includes identifying a parameter of the electrical shock and generating a report including the segment of the ECG and indicating the parameter of the electrical shock. The report is output or transmitted to an external device.

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 is a resuscitation device facilitating the administration of cardiopulmonary resuscitation to a subject, the resuscitation device comprising a housing having a top surface and a bottom surface, said top surface having a concave dell configured to guide on the top surface a hand positioning of a rescuer administrating a cardiopulmonary resuscitation to a subject, and said bottom surface configured to position and stabilize the housing over a sternum of the subject, and wherein the housing is configured to transmit a uniform distribution of the cardiopulmonary resuscitation force to the chest of the subject, said uniform distribution facilitates distributing the cardiopulmonary resuscitation force over a surface area that greater than the area of the top surface that directly receives the cardiopulmonary resuscitation force, thereby facilitating injury and contusion prevention to ribs and the sternum of the subject.

Concepts and technologies disclosed herein are directed to a smart automated external defibrillator (“AED”). According to one aspect of the concepts and technologies disclosed herein, the AED can present a menu that includes a plurality of modes. The plurality of modes can include a first responder mode, an Internet of Things (“IoT”) mode, and a general use mode. The AED can receive, via an input component, a selection, from the menu, of a mode from the plurality of modes. In response to the selection, the AED can configure a network connectivity component in accordance with a setting specified in the mode.

Aspects of the present disclosure are directed toward apparatuses, systems, and methods that include at least one medical device having a device transceiver configured to wirelessly broadcast a device signal including at least unique identifier data and an information system is configured to maintain an active list of medical device inventory associated with a particular emergency response vehicle, and the processor is configured to automatically determine presence of the at least one medical device.

A smart carry case which is effectively a portable GPS-enabled, AED monitoring system that is capable of monitoring an AED (as well as itself) and reporting back the presence, function and location of the AED to a remote host. Also disclosed is street furniture that is configured to retain, continuously monitor, and dispense an AED and communicate to a remote host (i.e., a control room). The street furniture is preferably configured such that a user presses the intercom button. In response, the street furniture contacts the control room. The control room, in turn, sends a signal to the street furniture causing the compartment to unlock so the AED can be removed and used in a rescue. The street furniture is configured to continuously monitor the AED and ensure it is functional, using a device such as has been described hereinabove. If the AED is used, an ambulance is deployed to the location. The AED that is retained in the compartment may be a smart carry case. As such, the presence, function, and location of the AED can be continuously monitored.

A system is provided for integrating at least one portable computing device with a resuscitative medical device such as a defibrillator. The system may include a carrying case coupled to the resuscitative medical device. The carrying case may include a storage space for the at least one portable computing device and a wireless charging system for charging the at least one portable computing device. The system may be configured to enable secure data transfer between each of the devices, including data communication and data storage. A processor of the resuscitative medical device may be configured to activate the wireless charging system and charge the at least one portable computing device under certain circumstances. The processor may further be configured to prioritize or optimize charging and data transfer between the resuscitative medical device and each of multiple portable computing devices.