Several embodiments of exhalation ports for use respiratory systems are described. Some of the embodiments provide an elongate body defining a lumen through which gases may flow. A plurality of tapered openings is arranged on a portion of the elongate body and configured to vent gases. A shroud extends from the elongate body and surrounds one or more of the plurality of tapered openings. The exhalation port is arranged to removably connect in-line with a circuit for delivering gases to a patient.

A face mask including a base model of a mask body having a front side and a back side and defining an interior. The back side includes a face opening within which a portion of a user face including a nose and mouth can be inserted and encompassed. The face opening is defined by a perimeter and is modified to substantially correspond to contours of the user face based on scan of topographical facial features of the user face.

The present technology relates to one or more of the screening, diagnosis, monitoring, treatment, prevention and amelioration of respiratory-related disorders. The present technology also relates to medical devices or apparatus, and their use. In particular, the present technology a headgear for supplying pressurised air to a patient, comprising a headgear tubing which is inflatable from a collapsed state to an inflated state to form a conduit for supplying pressurised air to the patient, and when the headgear tubing is in the collapsed state, the headgear tubing is elastically deformable and foldable on itself. The headgear may further comprise a rigidiser.

A biocontainment assembly for use with a patient suspected of having or diagnosed with a transmissible disease(s) capable of respiratory, airborne, contact, or droplet transmission includes a housing configured to be positioned over and at least partially enclose a head, neck, and/or torso of the patient. A sidewall of the housing includes an open portion contiguous with an at least partially pen bottom portion of the housing, sized to fit over at least a portion of the head, neck, and/or a torso of the patient. The housing also includes an airflow opening for evacuating fluid from an interior defined by the housing. The assembly also includes a drape configured to extend across the open portion of the sidewall having a first portion removably connected to the housing and an opposing second portion configured to be draped over the torso, abdomen, waist, and/or legs of the patient.

A reusable respirator including a mask adapted for covering and conforming to the face around the nose and a mouth of a user, a strap configured to secure the mask to a face of the user, and a filter component. All components of the respirator are capable of being cleaned, disinfected and sterilized at temperatures in excess of 50° C. An outer surface of the mask is substantially smooth and wettable for easily disinfecting and is shaped with a pair of outer shield portions for housing particulate air filters. The outer shield portions each include a closeable vent through the outer surface that is adapted to provide a user seal check and direct air flow through the outer surface for filtering by the respective particulate air filter, which is adapted to filter at least 95% of airborne particles.

A positive pressure ventilation apparatus may include a positive pressure mask; a positive pressure source; and an exhalation filter. The positive pressure mask may include a mask body having a patient-contact perimeter and including a flexible concertinaed portion of uniform flexion continuously around the mask body. The flexible concertinaed portion may include a plurality of ridges. The positive pressure mask may further include a gas inlet to the mask body configured to be connected to the positive-pressure source; and an adhesive seal positioned at the patient-contact perimeter which may be positioned at the outermost portion of the patient contact perimeter. The adhesive seal may comprise one or more layers. Each layer may include one or more cover members, each of which may include at least one removable tab; and at least one perforation. Each layer may further include a dual-sided form carrier with adhesive material on one or both sides.

Resuscitation/ventilation systems that include a pressure chamber or cylinder may use a piston articulated within the pressure chamber or shaft to push air and/or a mixture of gas and air into and out of an airway circuit for the purpose of providing mechanical ventilation and/or artificial respiration to a patient. In some cases, the pressure chamber or cylinder may be resident within a canister that fits with a body. The canister may include a motor that moves a shaft connected to the piston up and down, or in and out, within the pressure chamber or cylinder and this movement of the piston may cause a vacuum within the airway circuit and/or the pushing of air or gas out of the airway circuit into a patient’s lung(s).

Described herein are improved assisted ventilation interfaces along with methods and uses thereof. The interfaces comprises a hood embodiment with altered design aspects to decrease or even avoid the risk of leakage and potential viral transmittance along with providing other benefits. In one aspect, the patient interface comprises a hood with a free-breathing valve and an integral viral filter. The free-breathing valve and viral filter may be separate to or integral to the exhaust port. In a further embodiment multiple branches may be used from the exhaust port with multiple viral filters. In a further embodiment, an internal pressure gauge may be used. In a further embodiment dual air sources may be used.

Systems and methods are provided for aerosolizing and delivering therapeutic substances in an electronic aerosol delivery device with airflow regulation. Calibrated airflow resistance settings enable adjustment and control of flow velocity and or flow volume of air, aerosolized air, and or entrained aerosol particles, through the device, for optimal aerosol delivery among diverse conditions and applications.

A breathing mask includes a mask body unit and a container. The mask body unit includes a mask body having an inner surface configured to cooperate with a user's face to define an interior space therebetween, and two straps respectively connected to two opposite sides of the mask body. The container has a container body defining a chamber for receiving working liquid and formed with a plurality of vent holes for communicating the chamber with the interior space. At least one gas generating unit is connected to the container, and includes an electrolysis device disposed in a casing thereof for electrolyzing the working liquid into a hydrogen/oxygen gas mixture.