The present invention relates to a device, and software and methodology associated with a portable Automated External Defibrillator (“AED”). The portable AED works with a mobile device and software, and includes two or more cardiac pads, a battery pack, and specialized capacitor. When connected to a patient in cardiac arrest, the AED contacts Emergency Medical Services, and records patient information to be transmitted for evaluation by medical providers. The AED is able to analyze cardiac rhythms, suggests administering one or more shocks to the patient in appropriate cardiac arrhythmia, and guides a user on proper CPR technique, if enabled. The AED software can alert other personnel via a mobile device app.

A wearable health management system includes a flexible member configured to be worn on an affected area by a patient. At least one actuator is operably coupled to the flexible member. The at least one actuator is configured to be adjusted between a deployed state and a non-deployed state. At least one of a photoplethysmogram sensor and a bioimpedance sensor is coupled to the flexible member to obtain one or more health metrics from the patient. A controller is in communication with the at least one actuator. The controller is configured to adjust the at least one actuator to the deployed state to provide a selected pressure to the affected area.

A method for maintaining and/or increasing body temperature of a patient may involve delivering heat to a first location on a limb of the patient, delivering heat to a second location on the limb, apart from the first location, and applying intermittent compression to a third location on the limb, located between the first location and the second location. A device for maintaining and/or increasing body temperature of a patient may include a sleeve for positioning over at least part of one of the patient's limbs, first and second heat delivery members coupled with the sleeve, and an intermittent compression member coupled with the sleeve between the first and second heat delivery members.

Among other things, in one aspect, we describe a system for assisting with cardiopulmonary resuscitation (CPR). The system includes at least one sensor; and one or more processors configured for calculating a chest compliance relationship based on data received from the at least one sensor, and determining a neutral position of chest compression based at least in part on a feature of the chest compliance relationship. The system can take the form of an active compression-decompression device.

Various embodiments of systems, devices, components, and methods for providing external therapeutic vibration stimulation to a patient are disclosed and described. Therapeutic vibration stimulation is provided to at least one location on or adjacent to a patient's skin (such as through clothing or a layer disposed next to the patient's skin), and is configured to trigger or induce resonance or high amplitude oscillations in a cardiovascular system of the patient. Inducing such resonance can aid in training autonomic reflexes and improve their functioning.

Provided herein is an inflatable compression vest for performing compression therapy to a subject afflicted with a respiratory related condition, wherein the vest includes at least one column of inflatable bladders, linearly arranged whereby for each three consecutive bladders, a top bladder and a bottom bladder at least partially overlaps with a middle intervening bladder. Further provided are controller device configured to control operation of the compression vest in accordance with the breathing cycle of a subject, systems and methods of using the same.

An exemplary method of identifying a source of chest compressions administered during cardiopulmonary resuscitation (CPR) includes receiving, at a processor, signals indicative of pressure exerted during the chest compressions from at least one sensor communicatively coupled to the processor and disposed at a location on the victim's chest away from an indicated compression point for manual chest compressions, generating a compression waveform based on the received signals, detecting compression waveform features representative of the chest compressions based on the compression waveform, comparing the detected compression waveform features to a pre-determined criterion to discriminate between chest compressions from an automated compression device and manual chest compressions, determining whether the chest compressions are from the automated compression device or the manual chest compressions based on the comparison, and generating an output based on whether the chest compressions are determined to be from the automated compression device or the manual chest compressions.

The invention comprises an apparatus for arm exercise for therapy of a subject. The apparatus comprises a base comprising a planar upper surface. A first set of parallel rails are affixed to said upper surface of the base, the first set of parallel rails comprising a first rail and a second rail positioned parallel to each other and separated from each other by a predefined first distance. A second set of rails comprising at least a third rail having a first end and a second end are also provided, wherein said first end is slidably mounted on the first rail and said second end is slidably mounted on said second end. A sliding mount is slidably affixed to the second set of rails, and configured such that said sliding mount can be slidingly moved between the first end and the second end of the third rail.

The present invention concerns a device for controlling a robotic system for assisting the mobility of a user, said robotic system comprising at least one active mobility assistance element capable of assisting a given mobility action of the user, characterized in that the device comprises a detection system capable of detecting a compensatory movement of the user associated with the mobility action, said compensatory movement being a movement made by a user who is disabled, or able-bodied but locally and/or temporarily constrained, in order to perform at least part of the mobility action, and which at least partially substitutes the normal movement an unconstrained, able-bodied user would make in order to perform this mobility action, and a control system capable of controlling the at least one active element when the compensatory movement is detected.

A pain management device with a body portion having an elongate handle with an arm at one end for releasably attaching treatment attachments, the body portion having generally planar scraping wings for Gua Sha treatment, and a motor inside the body portion configured to impart vibration in each of several modes optimized for vibration therapy. The invention may also include a kit with the pain management device, and one or more treatment attachments designed for unilateral or bilateral vibration application adjacent to trigeminal and/or vagus nerves. The treatment attachment may have two or more pivotable arms that extend that extend perpendicular to the elongated handle when attached to the pain management. Also disclosed are methods of using the pain management device, in particular, for treating chronic and other pain and similar conditions.