A patient ventilation interface comprises a jet nozzle and a throat body that is arranged to receive ventilation gas output by the jet nozzle. The throat body defines a gas inlet and a gas outlet, with the gas inlet being open to ambient air. The patient ventilation interface further comprises a first pressure sensing tube having a pressure sensing port positioned within the throat body downstream of the jet nozzle and a second pressure sensing tube having a pressure sensing port positioned within the throat body downstream of the pressure sensing port of the first pressure sensing tube. A controller may be configured to calculate a mass flow based on pressure measurements taken at the pressure sensing ports of the first and second pressure sensing tubes.

The invention relates to a ventilator comprising a gas source, at least one gas path and a patient conduit and at least two valves, each of the valves having at least indirectly a port for the surrounding air and each of the valves being at least temporarily connected to the gas source and/or the patient conduit so as to conduct gas.

A jet ventilation assembly that has a conduit having a luer fitting on a proximal end and configured to fluidly couple the luer fitting to a distal end of the conduit and a centering assembly coupled to the conduit at the distal end. The centering assembly has a hub portion that is movable along the conduit.

A bi-level positive airway pressure device includes a housing that has a patient port for connecting to an airway of a patient. There is a device (e.g., a nozzle) for generating a positive airway pressure that is directed through a conduit towards the patient port. An exhalation detector includes a nozzle emitting a jet of a gas directed across the conduit and directed at a receptor channel when exhalation gases flow from the patient port, thereby an increase a gas pressure is present at the receptor channel when the exhalation gases flow from the patient port. The exhalation detector converts the increase in the gas pressure into a movement of an occluding member such that when the exhalation gases flow from the patient port, the occluding member moves to block the means for generating the positive airway pressure.

Described is an apparatus for oxygenation and/or CO2 clearance of a patient, comprising: a flow source or a connection for a flow source for providing a gas flow, a gas flow modulator, a controller to control the gas flow, wherein the controller is operable to: receive input relating to heart activity and/or trachea gas flow of the patient, and control the gas flow modulator to provide a varying gas flow with one or more oscillating components with a frequency or frequencies based on the heart activity and/or trachea flow of the patient.

Several methods of supporting respiratory function of a patient before, during and/or after a medical procedure are disclosed. In certain arrangements, supporting respiratory function while a patient is under general anaesthesia can include providing a high gas flow a high gas flow that is greater than 15 L/min while the patient is under general anaesthesia. In certain arrangements, a method of providing ventilation while a patient is under general anaesthesia involves providing only a gas flow delivered through a nasal interface that is greater than 15 L/min while the patient is under general anaesthesia.

A patient circuit of a ventilation system, such as a non-invasive open ventilation system, wherein the patient circuit comprises a nasal pillows style patient interface that incorporates at least one Venturi effect jet pump proximal to the patient. The patient circuit further comprises a pair of uniquely configured 3-way connectors which, in cooperation with several uniquely configured tri-lumen tubing segments, facilitate the cooperative engagement of the patient interface to a ventilator of the ventilation system.

Systems, methods, and devices for humidifying a breathing gas are presented. The system includes a base unit, a vapor transfer unit, a nasal cannula, and a liquid container. The base unit includes a blower. The vapor transfer unit is external to the base unit and includes a gas passage, a liquid passage, a gas outlet, and a membrane separating the gas passage and the liquid passage. The membrane permits transfer of vapor into the gas passage from liquid in the liquid passage. The nasal cannula is coupled to the gas outlet. The liquid container is configured to reversibly mate with the base unit.