The present invention provides a method for delivering a substance to the nasal cavity of a subject in which drawing air from a mouthpiece triggers release of a substance to a subject's nasal cavities. The device comprises a container for containing the substance in fluid communication with a nosepiece, a valve with an active configuration and an inactive configuration, and a trigger mechanism to reconfigure the valve from its inactive configuration to its active configuration and vice versa. Drawing air from the mouthpiece, e.g., when the subject takes in air by mouth, activates the trigger mechanism, thereby reconfiguring the valve from its inactive configuration to its active configuration for a predetermined period of time and delivering the substance from the device to a nasal cavity of the subject.

A device provides respiratory treatment such as for sleep disordered breathing and other respiratory conditions in a discreet configuration to provide a minimally invasive system. The system may include a flow pressurizer apparatus configured to generate a pressurized flow of air through a small bore delivery conduit toward a patient interface. The system may further include a treatment compensator coupled with the fine bore delivery conduit. The treatment compensator may be configured at the patient interface to reduce pressure for patient inspiration. A processor may control adjustments to the pressure generated by the flow pressurizer apparatus.

A pneumatic oxygen conserver delivering a constant minute flow volume rate to a nasal mask, face mask, or nasal cannula is rendered lightweight by using tubing connected between the conserver and an oxygen source as a reservoir of oxygen for delivery to the nasal mask, face mask, or nasal cannula.

A pressure swing adsorption oxygen generator to separate oxygen from air for use with a pressure source generating a high pressure and a low pressure. The pressure swing adsorption oxygen generator includes an adsorption bed having a bed of nitrogen absorbent material; and a multi-position rotary valve for controlling pressure swing adsorption of the adsorption bed, and being couplable to the pressure source for fluid communication therewith and in fluid communication with the adsorption bed. The rotary valve includes a cam having first and second rotary positions, in the first rotary position of the cam the rotary valve communicating high pressure generated by the pressure source to the adsorption bed and in the second rotary position of the cam the rotary valve communicating low pressure generated by the pressure source to the adsorption bed.

A pneumatic system for delivering oxygen to a subject, including an oxygen supply channel having an inlet, a patient delivery outlet and an exhaust; and a flow control element configured to control the flow from the oxygen inlet to the patient delivery outlet, or to the exhaust; wherein inhalation by the patient causes the flow control element to assume a first position, allowing oxygen to flow from the oxygen inlet to the patient delivery outlet; and wherein exhalation by the patient causes the flow control element to assume a second position, directing oxygen flow from the oxygen inlet to the exhaust.

A ventilator with an integrated cough assist for use with a patient circuit in fluid communication with a patient connection of a patient, and operable in a ventilation mode and in a cough-assist mode. The ventilator includes a user input for switching operation from ventilation mode to cough-assist mode without disconnecting the ventilator from the patient, and a controller operable in response to the user input and controlling operation of the ventilator in cough-assist mode to provide for at least one cough assist to the patient having an insufflation phase followed by an exsufflation phase. A cough-assist valve in a first state for the insufflation phase communicates a positive pressure to the ventilator connection and in a second state for the exsufflation phase communicates a negative pressure to the ventilator connection.

A gas concentrator apparatus for supplying a gas to a patient and preventing leakage of the gas when a supply tube is removed from the gas concentrator apparatus includes a gas storage tank, a chamber, a piston, a membrane, a spring member, and the supply tube. The chamber is in gaseous communication with a gas storage tank for receiving the gas from the gas storage tank. The chamber comprises a piston configured to move the chamber in a forward direction or a reverse direction. The membrane is positioned at an end of the chamber distal to the gas storage tank. The membrane is actuated by a spring member to seal an entrance of the supply tube for preventing leakage of the gas when the supply tube is removed from the gas concentrator apparatus.

A device for detecting a flow of respiration in a conduit includes a source of a gas jet interfaced to a side of the conduit. The source of the gas jet emits a jet of gas aimed across the conduit. A main port is interfaced to a distal side of the conduit for receiving the jet of gas and a pressure-detecting device is interfaced to the main port. In absence of the flow within the conduit, the gas jet enters the main port and the pressure-detecting device reports a first pressure. In presence of the flow within the conduit, the gas jet is deflected away from the main port by the flow and the pressure-detecting device reports a second pressure, the second pressure being lower than the first pressure.

A breathing assistance apparatus includes an inner volumetric member pressurizable from a first pressure to a second pressure and an outer volumetric member surrounding at least a portion of the inner expandable volumetric member. The inner volumetric member pressurizes the outer volumetric member as the inner volumetric member is pressurized from the first pressure to the second pressure. In another embodiment, a breathing assistance apparatus includes exhalation and inhalation chambers with respective biasing members providing for the exhalation chamber to apply a pressure to the inhalation chamber and thereby provide assisted inhalation. Methods for assisting breathing are also provided.

The present invention provides a method for delivering a substance to the nasal cavity of a subject in which drawing air from a mouthpiece triggers release of a substance to a subject's nasal cavities. The device comprises a container for containing the substance in fluid communication with a nosepiece, a valve with an active configuration and an inactive configuration, and a trigger mechanism to reconfigure the valve from its inactive configuration to its active configuration and vice versa. Drawing air from the mouthpiece, e.g., when the subject takes in air by mouth, activates the trigger mechanism, thereby reconfiguring the valve from its inactive configuration to its active configuration for a predetermined period of time and delivering the substance from the device to a nasal cavity of the subject.