The present invention provides a particulate delivery device with an automatic activation mechanism that pierces or cuts a composition capsule when a cap is removed. The cap cannot be replaced once the device is activated for use. The device allows for gas flow through the device from a gas inlet to a gas outlet through a composition receptacle and dispersion chamber to deliver particulate to the airway of a subject.

Described herein are various embodiments of systems and devices operable to detect individual oxygen delivery events at a user body region which are associated with external oxygen boluses administered to a user. Such devices and system may be useful, for example, in assessing the efficacy of cardiopulmonary resuscitation (CPR) or intubation.

A system includes a guidance device that provides feedback to a user to compress a patient's chest at a rate of between about 90 and 110 compressions per minute and at a depth of between about 4.5 centimeters to about 6 centimeters. The system includes a pressure regulation system having a pressure-responsive valve that is configured to be coupled to a patient's airway. The pressure-responsive valve is configured to remain closed during successive chest compressions in order to permit removal at least about 200 ml from the lungs in order to lower intracranial pressure to improve survival with favorable neurological function. The pressure-responsive valve is configured to remain closed until the negative pressure within the patient's airway reaches about −7 cm H.sub.2O, at which time the pressure-responsive valve is configured to open to provide respiratory gases to flow to the lungs through the pressure-responsive valve.

A rescue device for a choking victim and a method of rescuing a choking victim is provided. The device includes a first tube that is configured to be inserted into the victim's mouth so as to assist in dislodging a foreign object in the victim's windpipe by creating a low-pressure environment within the victim's mouth. The device further includes a second tube that is configured to allow a rescuer to create the low-pressure environment in the victim's mouth by sucking on a second tube of the device. A filter is positioned between the first and second tubes to reduce sanitary concerns and to prevent the foreign object from becoming lodged in the rescuer's windpipe.

The present invention provides a particulate delivery device with an automatic activation mechanism that pierces or cuts a composition capsule when a cap is removed. The cap cannot be replaced once the device is activated for use. The device allows for gas flow through the device from a gas inlet to a gas outlet through a composition receptacle and dispersion chamber to deliver particulate to the airway of a subject.

The present invention comprises an insufflated air inlet (2a), an outlet (3a) for said insufflated air provided at the lower end of an air conveying tube (3) designed to penetrate the throat of the victim through the mouth, at least a first one-way valve (4) interposed between said air inlet (2a) and air outlet (3a) to allow the flow of air from said inlet (2a) to said outlet (3a) and prevent the flow of a fluid exhaled by the victim in the opposite direction, the body of said valve (4) including an outlet aperture (4a) for the exit of the fluid exhaled by the victim, and characterized in that the upper end of said insufflated air conveying tube (3) comprises a portion (3b) of tube (3) which is configured for internally receiving the body of said valve (4), the wall of said tube (3) including at least one outer hole (6) communicating with the aperture (4a) of the body of the valve (4) to allow discharging the fluid exhaled by the victim to the outside.

Resuscitation devices for performing external chest compression (ECC) and defibrillation on a person and methods using the devices are disclosed. The disclosed devices can include chest compression members and a communication module that can communicate with a remote command center. The disclosed devices can also include an optional defibrillation module that may be integrated. The devices can be coupled to a backboard and can include physiological sensors, electrodes, wheels, controllers, human interface devices, cooling modules, ventilators, cameras, and voice output devices. Methods can include defibrillating, pacing, ventilating, cooling, and performing ECC in an integrated, coordinated, and/or synchronous manner using the full capabilities of the device. Some devices include controllers executing methods for automatically performing the coordinated activities utilizing the device capabilities.

Among other things, we describe a system that includes a first medical device for treating a patient at an emergency care scene, the first medical device including a processor and a memory configured to detect a request for a connection between the first medical device and a second medical device for treating the patient at the emergency care scene, the request for connection including an identifier of the second medical device, responsive to receiving the request for connection, enabling a wireless communication channel to be established between the first medical device and the second medical device based on the identifier of the second medical device and an identifier of the first medical device; and enabling transmission and/or exchange of patient data between the first medical device and the second medical device via the wireless communication channel. Such communications with more than two devices may also be possible.

Described herein are various embodiments of systems and devices operable to detect individual oxygen delivery events at a user body region which are associated with external oxygen boluses administered to a user. Such devices and system may be useful, for example, in assessing the efficacy of cardiopulmonary resuscitation (CPR) or intubation.

An inspiratory resistor valve system (IRV) to regulate intrathoracic pressure during positive pressure breathing, spontaneous inspirations, and CPR may include an inspiratory port. The IRV system may include patient port. The IRV system may include a separate expiratory port. The IRV may include a plurality of atmospheric pressure sensitive valves. The plurality of atmospheric pressure sensitive valves may isolate the expiratory port and the inspiratory port from one another.