A system and approach for integrating of health parameters from wearable cloud connected access control devices to provide life safety measures, and also for controlling access to facilities. A monitoring system may incorporate a device for a wearer or holder and a sensor at an entrance to or exit from a specified facility, and a processor connected to the sensor. The device may sense a parameter of the wearer or holder selected from a group of items incorporating heartbeat, blood pressure, blood oxygen, pulse rate, and body temperature. If the selected parameter indicates an abnormal or worsening condition, then the wearer or holder may obtain access to a hospital or health care facility. Health professionals may hold or wear a device that permits them to enter a restricted facility to aid a person within the facility needing medical assistance.

A flow sensor system for ventilation treatment comprises a flow conduit configured to allow gas flow between a first region and a second region, the flow conduit defining a lumen for the gas flow; a flow restrictor disposed within the lumen of the flow conduit between the first region and the second region; a first absolute pressure sensor disposed adjacent to the first region of the flow conduit and configured to measure a pressure of the gas flow at the first region of the flow conduit; and a second absolute pressure sensor disposed adjacent to the second region of the flow conduit and configured to measure pressure of the gas flow at the second region of the flow conduit.

A defibrillating system includes a processor coupled to a memory. The processor and the memory are configured to identify a treatment event associated with treatment of a victim with the defibrillating system, and transmit a representation of a portion of an ECG signal associated with the identified treatment event. In some cases, the processor and the memory are configured to identify the portion of the ECG signal associated with the identified treatment event. In some cases, the portion of the ECG signal is of a predetermined length of time having a start time and an end time based on a time associated with the identified treatment event.

In vivo monitoring devices and systems for enzymes and/or analytes including devices having a reactant reservoir are provided.

The technologies described herein are generally directed to facilitating operation of a health network control system. In accordance with one or more embodiments, systems described herein can include a processor, and a memory that can store executable instructions that, when executed by the processor, can facilitate performance of operations that can include facilitating receiving, from transceiver of a second device, a first signal that can describe an event related to treatment of the treatment subject. Further, the operations can include, based on an analysis of the subject information, the event information and facility information representative of a group of treatment facilities, selecting a treatment facility that can perform the treatment of the treatment subject, resulting in a selected treatment facility, and facilitating communicating via a second signal to the transceiver of the second device, selected facility information corresponding to the selected treatment facility.

A feedback device for an acute care provider includes: at least one motion sensor; a haptic output component for providing feedback having a varying haptic pattern to the acute care provider regarding performance of a resuscitation activity; and a controller. The controller can be configured to receive and process a signal representative of performance of the resuscitation activity from the at least one motion sensor, compare the acute care provider's performance of the resuscitation activity to a target performance of the resuscitation activity, and cause the haptic output component to provide haptic feedback to the acute care provider by changing the haptic pattern based, at least in part, on the signal from the at least one motion sensor and the comparison of the acute care provider's performance to the target performance of the resuscitation activity. The device can be adapted to be wrist-worn by the acute care provider.

A system for providing a visual summary of a condition of a patient when traumatic brain injury (TBI) is suspected or diagnosed includes at least one patient condition sensor configured to sense data representative of a patient condition parameter of interest for a TBI patient; at least one airflow sensor configured to sense data representative of ventilations provided to the patient; at least one visual display for providing the visual summary to a user; and at least one controller. The at least one controller is configured to cause the visual display to provide the visual summary. The visual summary can include at least one visual representation of at least one patient condition parameter for each time interval of a plurality of time intervals, at least one visual representation of ventilation information, and a visual indication of when at least one patient condition parameter is outside of a target range.

A system for monitoring and responding to a cerebrovascular accident includes a computer, including a computer processor and a computer transceiver, a storage that stores personal medical information and a risk level, and a portable device attached to a user. When the computer transceiver receives personal medical information of the user, the computer processor calculates the risk level of a cerebrovascular accident based on the personal medical information. When the computer transceiver receives acceleration information, the computer processor determines whether to contact a predetermined contact based on the risk level and the personal medical information. The portable device includes an acceleration sensor, a position receiver, a clock, a portable transceiver, and a portable processor.

A method and system for continually monitoring oxygenation levels in real-time in compartments of an animal limb, such as in a human leg or a human thigh or a forearm, can be used to assist in the diagnosis of a compartment syndrome. The method and system can include one or more near infrared compartment sensors in which each sensor can be provided with a compartment alignment mechanism and a central scan depth marker so that each sensor may be precisely positioned over a compartment of a living organism. The method and system may comprise hardware or software (or both) may adjust one or more algorithms based on whether tissue being monitored was traumatized or is healthy. The method and system can also monitor the relationship between blood pressure and oxygenation levels and activate alarms based on predetermined conditions relating to the oxygenation levels or blood pressure or both.

A wearable diagnostic electrocardiogram (ECG) garment is disclosed herein. The wearable diagnostic ECG garment comprises a garment body, screen-printed electrodes positioned on the body, and screen-printed wires positioned in the garment body, each of the screen-printed wires connected from a central connector module to a screen-printed electrode.