A nasal prong comprising a tube configured to be partially placed in a nasal passage of a patient, the tube having a first end, a second end, and an intermediate portion, and a lumen extending therebetween. The first end having an elongated opening configured to face supero-medially within the nasal passage, wherein airflow out of the elongated opening is directed superiorly and posteriorly within the nasal cavity, above the inferior concha, around the middle concha, and towards the roof of the nose. The intermediate portion of the tube having a bend that keeps the nasal prong on a floor of the nasal passage at and/or near the outer edge of a nostril.

Disclosed herein are facially fitting devices, such as nasal cannulas and oxygen masks, including illuminating placement marker(s), which facilitate correct placement of the facially fitting devices on a face of a subject in dark conditions. The placement marker is powered by a thermo-electric generator, which generates electrical power via thermal coupling thereof to skin on the face of a subject when the facially fitting device is fitted, or partially fitted, on the face of the subject.

Nasal cannulas are described herein. The nasal cannula (110) includes a cannula housing (112), a reservoir (160), a nebulizer channel (154), and a gas channel (120). The cannula housing includes at least one nasal extension (116) extending from the cannula housing, wherein the at least one nasal extension is configured to be disposed within a patient's nares. The reservoir includes a reservoir volume configured to dispense a medicament. The nebulizer channel is in fluid communication with the reservoir volume and the at least one nasal extension. The gas channel is configured to direct a gas flow toward the at least one nasal extension through the nebulizer channel, drawing a portion of the medicament from the reservoir through the nebulizer channel with the gas flow toward the at least one nasal extension.

The present technology relates to a patient interface for delivery of a flow of pressurised air to an entrance of a patient's airways, the patient interface comprising a mask with a seal-forming structure and one or more positioning and stabilising structures configured to provide a force to hold the mask in a therapeutically effective position on a patient's head in use. The mask and one or more of the positioning and stabilising structures includes a connection port to receive an end of the air circuit. The pressurised air is delivered from the air circuit to the seal-forming structure. In use, the patient connects the air circuit to the connection port of choice, depending on whether they prefer the patient interface to be arranged such that the end of the air circuit is superior to the patient's otobasion superior or inferior to the patient's otobasion superior.

Methods and apparatus provide controlled operations in an oxygen concentrator (100) such as by adjusting valve opening time to regulate amount of oxygen enriched air released to a user. The apparatus may generate, with a sensor configured to sense pressure at a location associated with accumulation of enriched air produced by the concentrator, a signal representing measured pressure of the accumulated enriched air. The apparatus may generate, with a sensor, a signal indicative of respiration of a user of the concentrator. The apparatus may include a controller configured to receive the measured pressure and respiration signals. The controller may control, responsive to the respiration indication and according to a target duration, actuation of a valve adapted to release a bolus of accumulated oxygen enriched air. The controller may dynamically determine the target duration during the release of the bolus according to a function of a value of the measured pressure.

A high flow therapy system for delivering heated and humidified respiratory gas to an airway of a patient includes a respiratory gas flow pathway for delivering the respiratory gas to the airway of the patient by way of a non-sealing respiratory interface; wherein flow rate of the respiratory gas is controlled by a microprocessor, a mixing area for mixing a first gas and a second gas in the respiratory gas flow pathway, a humidification area downstream of the mixing area and configured for humidifying respiratory gas in the respiratory gas flow pathway, and a heated delivery conduit for minimizing condensation of humidified respiratory gas.

An illustrated view of a non-kinking air hose for preventing an air hose from kinking is presented. The non-kinking air hose is useful for providing an air flow from an air tank to a patient where the air hose is prevented from forming a kinking condition. The non-kinking air hose further prevents damage or reduced/zero air flow from an air tank to a patient.

A respiration assistance device includes a nasal respiration assisting section for supplying a gas to the nasal cavity of a living body. The nasal respiration assisting section includes: a first gas supplying portion which supplies a gas below one of the nostrils of the living body; a second gas supplying portion which supplies the gas below the other nostril of the living body; a first tube connecting portion to which a tube for supplying the gas to the first gas supplying portion is connectable; and a second tube connecting portion to which a tube for supplying the gas to the second gas supplying portion is connectable.

A breathing assistance apparatus is configured with features that improve serviceability of the apparatus. The apparatus can include animations to provide instruction regarding correcting easily-identified fault conditions and to provide instruction regarding routine maintenance routines. The apparatus also can be configured with top level control menus that are obscured in a manner to limit manipulation of the top level control elements by unauthorized users.

A passive oxygen mask and vacuum regulation system disposed in fluid communication with a vacuum scavenging array includes a passive oxygen mask dimensioned to fit over a patient's nose and mouth and having a gas inlet port and an expired gas outlet port. A vacuum regulation assembly has a vacuum regulator which includes an expired gas discharge tube disposed in fluid communication between the passive oxygen mask and the vacuum regulation assembly, and a vacuum suction tube disposed in fluid communication between the vacuum regulation assembly and the vacuum scavenging array. The vacuum regulation assembly further comprising a vacuum attenuation port through a portion of a regulator housing, wherein the vacuum attenuation port is at least partially defined by an attenuation port diameter dimensioned to reduce a vacuum suction pressure in the expired gas discharge tube to a predetermined vacuum suction pressure.