A patient interface device includes a headgear assembly (20) having at least two strap member (22). The strap members (22) each include a flexible body and a bladder assembly (50). In one embodiment, bladder assemblies (50) may be selectively inflated and deflated. In the inflated, or first, filled configuration, headgear assembly (20) defines a three-dimensional shape sized to fit about a patient's head. In the deflated, or second, collapsed configuration, the head gear assembly (20) may be placed in a flat or other compact configuration.

A gas-washout vent includes a housing with a first wall with one or more passages through the wall configured to provide fluid communication with a portion of the patient interface system exposed to a therapy pressure. The passages include respective first openings on a first surface of the first wall. The housing at least partially defines a second opening in communication with ambient atmosphere. A diffusing material is located at least partially within the housing to be adjacent the first surface. A surface of the diffusing material facing the first surface is spaced away from the first surface by a gap that extends to provide a fluid communication between all of the first openings and between all of the first openings and the second opening. The housing is configured so that air is prevented from flowing out of the housing at all areas directly opposite each of the first openings.

A universal respiratory detector for detecting a respiratory gas. The universal respiratory detector may include a plurality of layers with a visual indicator to quickly and reversibly change color to detect a respiratory gas parameter such as carbon dioxide. The color change may be visible from both sides of the detector. In some examples, the respiratory detector may be a biocompatible and conformable sticker for mounting on a person's face or an oxygen delivery device.

A device for providing a known concentration of blended air and oxygen, or oxygen, to an individual which incorporates a face mask inside a hood, thereby preventing aerosolization of potentially harmful exhaled gases and controlling condensation issues within the hood while under pressurized conditions. The air tight seal required to allow placement and removal of the hood on the individual will be manufactured using injection molded elastomers to over-mold injection molded rigid plastic components.

The present disclosure relates to a system for prevention of sudden death that includes a wearable seizure detection device; a base unit; and a computer, the computer configured to receive input from the seizure detection device and trigger the base unit to release oxygen under a condition effective to enrich an environmental oxygen level and prevent sudden death when the input indicates a seizure. Also disclosed is a portable system for preventing sudden death, where the system includes an oronasal mask; a compressed oxygen cartridge, wherein the compressed oxygen cartridge is coupled to the oronasal mask; and a fastener, wherein the fastener is coupled to the oronasal mask, wherein the system releases oxygen upon activation under a condition effective to enrich an environmental oxygen level and prevent sudden death. Further disclosed are methods of preventing sudden death comprising enriching an environmental oxygen level for a subject using the systems described.

Some embodiments of an inhalation exposure system can deliver a gas, such as an aerosol, through a manifold to a set of exposure chambers in a controlled manner so as to achieve improved consistency for all of the test subjects.

The present technology relates to respirator devices including source control features. In some embodiments, a source control mask device can include a shield that substantially covers the mouth and nose of a user and a mechanism that can actively extract air as it is exhaled by the user. The extracted exhaled air can then be sanitized before the mask device discharges it into the atmosphere. The mask device may selectively form a seal to the user's face dependent on air flow conditions.

An artificial ventilation system and relative control method, the ventilation system is suitable for application to CPAP (Continuous Positive Airway Pressure) breathing helmets to provide artificial ventilation to a patient with respiratory difficulties destined for so-called “sub-intensive” therapies. The artificial ventilation system provides a fully automated ventilation and does not require frequent checks by specialized medical personnel. The relative control method allows automatic control of the entire artificial ventilation system and implements innovative control strategies and techniques.

A method of an apparatus control pressure in the patient interface. A vent valve may be used with a respiratory device, where the vent valve may selectively block fluid communication between components, such as the flow generator, the patient interface, and/or the vent. An expiratory flow model may be used to determine an expiratory characteristic such as an expiratory flow rate or pressure in the patient interface where an indicative measure may not be available. The expiratory flow model may receive inputs based on a measure of the patient's respiration, such as the tidal volume, peak inspiratory flow rate or length of inspiration. The expiratory characteristic may be used by a controller to control a pressure in the patient interface to provide respiratory therapy to a patient at or close to a target pressure.

There is provided a respirator for supplying clean air for a wearer. The respirator comprises a face assembly comprising an oronasal mask configured to seal against and cover a nose region and a mouth region of the wearer. The face assembly may be configured to be interchangeable on the respirator between a half-face assembly and a full-face assembly. The respirator comprises a securing headgear releasably securable with the face assembly, the securing headgear assembly configured to secure the respirator on a head of the wearer. The respirator comprises a facepiece assembly for supplying the wearer with air for inhaling and releasing air exhaled by the wear, the facepiece assembly releasably securable with the face assembly. One or more of the face assembly, the facepiece assembly, or the securing headgear are configured to be released from the respirator, sterilized, and releasably resecured with the respirator.