Abstract: A method for wide area ventilation management. The method includes wirelessly accessing ventilator data generated by a plurality of networked ventilators, wirelessly transmitting patient information to the plurality of networked ventilators, wherein the patient information facilitates in contextualization of the ventilator data; and wirelessly transmitting protocols and rules to the plurality of networked ventilators.

Abstract: A method for implementing a ventilator protocol on a ventilator. The method includes accessing the ventilator protocol, and automatically implementing the ventilator protocol on the ventilator via a touch screen display of the ventilator.

Abstract: A method for bi-directional ventilator communication includes receiving a communication, at the ventilator, from a medical entity, wherein the communication is associated with ventilator manipulation. The method also includes transmitting ventilator information, by the ventilator, to the medical entity wherein the ventilator information is associated with the ventilator manipulation.

Abstract: A method for contextualizing ventilator data. The method includes accessing ventilator data, wherein the ventilator data is generated by a ventilator, accessing context data, and associating the ventilator data with the context data such that the ventilator data is contextualized.

Abstract: A method for implementing ventilator rules on a ventilator. The method includes accessing ventilator rules for the ventilator; determining a mode of operation of the ventilator; and in response to the determined mode of operation, implementing at least one of the ventilator rules.

Abstract: A method for health care facility ventilation management. The method includes accessing ventilator data generated by a ventilator; providing patient information for the ventilator, wherein the patient information facilitates in contextualization of the ventilator data; and providing protocols and rules for said ventilator.

Abstract: A ventilator comprising a ventilator component module. The component module includes a receiver for receiving a communication from a medical entity, a transmitter for transmitting ventilator information to the medical entity, a processor, memory, a touch screen, and a scanner configured for scanning identifiers.

Abstract: A carbon-dioxide sampling device for non-invasively measuring carbon dioxide in exhaled breath. The device includes a breath-sampling chamber and a carbon-dioxide collector. The breath-sampling chamber is configured to be disposed over a respiratory opening of a patient, and is also configured to seal with the patient's face preventing unintentional leakage of respiratory gases from the chamber. The carbon-dioxide collector is disposed in the breath-sampling chamber in fluid dynamic isolation from the respiratory gases. Moreover, the carbon-dioxide collector is configured to be disposed in proximity to, and outside of, the respiratory opening of the patient, and to collect a sample of exhaled breath from the patient.

Abstract: A ventilation mask comprises a corrugated flexible seal, and a plurality of ridges disposed along the corrugated flexible seal. The corrugated flexible seal is configured for establishing a fluid seal between the ventilation mask and a patient, and for allowing facial movements of the patient while maintaining the fluid seal. The plurality of ridges disposed along the corrugated flexible seal is configured for physical contact with the patient.

Abstract: A mask for patient ventilation comprises a frame portion, a retention portion, and a connector portion. The frame portion is for surrounding a respiratory opening of a patient. The retention portion is for maintaining positive pressure between the frame portion and the patient. The connector portion is for connecting delivery tubes to the mask. The connector portion is configured such that the connector only couples with compatible components.

Abstract: A non-invasive ventilation patient interface comprises a fresh gas entry port, a frame, and a zygomatic facial interface. The fresh gas entry port is configured for coupling with a fresh gas supply. The frame is configured for coupling with a head strap system, wherein the head strap system is configured for supplying a securing force to secure the patient interface in a position over a respiratory opening of a patient. The zygomatic facial interface is coupled with the frame and configured for spreading the securing force away from a nasal bridge of the patient and onto left and right zygomatic arch regions of the patient.

Abstract: A ventilation mask for sealing on a face of a patient comprises a nasal passage opener configured for facilitating in opening the nasal passage of the patient. The nasal passage opener is disposed over a nasal valve of the patient when the ventilation mask is sealed on the face of the patient.

Abstract: A carbon-dioxide sampling system for accurately monitoring carbon dioxide in exhaled breath. The system includes a ventilator. The ventilator is configured to ventilate a patient with respiratory gases. The ventilator includes a carbon-dioxide sampling control unit and a carbon-dioxide analyzer. The carbon-dioxide sampling control unit is configured to control the timing of sampling of carbon dioxide in the exhaled breath of a patient, and to control the timing of the analysis of exhaled gases by the carbon-dioxide analyzer.

Abstract: A non-invasive ventilation patient interface comprises a fresh gas entry port, an exhaust gas vent port, and a filter media disposed in the exhaust gas vent port. The fresh gas entry port is configured for coupling with a fresh gas supply. The exhaust gas vent port is configured for allowing expulsion of exhaust gas from the patient interface in response to exhalation of a patient. The filter media is configured for filtering contagious from the exhaust gas, diffusing the exhaust gas, and controlling an expulsion flow of the exhaust gas through the exhaust gas vent port.

Abstract: A non-invasive ventilation patient interface comprises a frame, a facial skin interface, and a self-sealing tube insertion region. The frame is configured for coupling with a head strap system, where head strap system is configured for supplying a securing force to secure the patient interface in a position over a respiratory opening of a patient. The facial skin interface is coupled with the frame and configured for interfacing with facial skin of the patient and sealing the patient interface about the respiratory opening in response to the securing force. The self-sealing tube insertion region is coupled with the facial skin interface and configured for self-sealing about a tube disposed between the facial skin and the facial skin interface, such that the securing force is diverted around the tube while the tube is inserted in the self-sealing tube insertion region.