A respiratory therapy system configured to deliver gases to a patient can have a non-sealed gas flow generating arrangement configured to deliver a high flow of positive gas to an airway of a patient and a negative flow of gas away from an airway of the patient. The positive and negative flows of gas can be generated simultaneously. The flow of positive and negative gases reduces exhaled gases in anatomical dead spaces of the patient.

The present invention provides a gas generator and comprises an electrolytic device, a condensing filter device, and a cooling device. The electrolytic device is configured for electrolyzing electrolyzed water to generate hydrogen. The condensing filter device is coupled to the electrolytic device for receiving and filtering the hydrogen generated by the electrolytic device. The cooling device comprises a cooling sheet and a cooling fan, wherein the cooling sheet is configured on the condensing filter device, and the cooling fan is configured for driving air to flow through the cooling sheet to cool the condensing filter device. The present invention uses the condensing filter device and the cooling device for cooling the generated gas and the component that gas passes through, so that a stable operating temperature is maintaining. Therefore, the possibility of the component damage by high temperature and humidity is reduced.

A combination positive airway pressure (PAP) or continuous positive airway pressure (CPAP) and resuscitation system and related methods. The systems can be well-suited for use in providing CPAP therapy for a neonate or infant patient, with the ability to also provide resuscitation therapy at a peak inspiratory pressure (PIP) as needed or desired without switching to another system or switching the patient interface. The system can include an expiratory pressure device capable of regulating a positive end expiration pressure (PEEP) of the system, which preferably can also induce pressure oscillations relative to a mean PEEP.

Systems and methods provide a self-contained, intermittent positive airway pressure system for treating sleep apnea, snoring, and other respiratory disorders. The systems and methods provide an air flow director that can be worn in or over the nose of the individual in communication with an upper airway. The systems and methods provide an airflow regulation assembly that can also be worn in its entirety by the individual in communication with the air flow director. The airflow regulation assembly includes a source of positive pressure. The airflow regulation assembly intermittently operates the source of positive pressure to increase positive air pressure in the air flow director sufficient to resist tissue collapse in the upper airway during only a portion of the respiratory cycle less than the entire respiratory cycle.

An apparatus for supplying a respiratory gas includes a conveyor device for conveying the respiratory gas, a conduit for feeding the respiratory gas to a person, and a humidification device for humidifying the respiratory gas. A sensor device is configured to generate a signal indicative of the respiratory gas humidity and a control device is configured to control the humidification device with regard to the signal A method of supplying a respiratory gas to a patient, in which the respiratory gas is introduced by means of a conveyor device into the conduit leading to the patient and is humidified, includes operating the conveyor device so that a respiratory gas pressure which is above ambient pressure is provided in the conduit, and adjusting the humidity on the basis of signals indicative of the relative and/or absolute humidity of the respiratory gas generated by the sensor device.

An air conduit for a respiratory therapy device comprises a first end, a second end, and a tube portion, wherein the tube portion comprises a tube wall and an auxiliary structure, such as a rib. The air conduit may deliver a flow of air from a respiratory therapy device or a humidifier to a patient interface. The air conduit may comprise a plurality of auxiliary structures, some of which may consist of a polymeric material, and some of which may comprise a polymeric material and an electrical conductor. An auxiliary structure may be a helical rib extending across a length of the tube portion.

A breathing circuit includes a flexible hollow tube having a generally circular cross section and a flexible printed circuit board assembly disposed in the flexible hollow tube. The flexible printed circuit board assembly defines part of at least one inspiratory passage within the flexible hollow tube and part of at least one expiratory passage within the flexible hollow tube. The flexible printed circuit board assembly is configured to heat airflow within one or more of the at least one inspiratory passage and the at least one expiratory passage, and monitor a first property of the airflow within one or more of the at least one inspiratory passage and the at least one expiratory passage at multiple locations along the axial length of the flexible hollow tube.

A system and method are configured to utilize patient effort to increase cough flow of a subject by limiting airway collapse by causing a series of exsufflation events over an individual exhalation of the subject. A single exhalation of the subject is segmented into a series of exsufflation events by a processor configured to toggle a pressure regulator between a first airway closed mode and a second airway open mode. The processor is configured such that the transitions between the closed and open modes are initiated based on predetermined timing or based on output signals generated by sensors monitoring one or more gas parameters (for example, pressure) in the airway of the patient.

A system for humidifying respiratory gases has a humidification apparatus, a humidification chamber, a heating apparatus and a sensor. The sensor is configured to determine a characteristic of the gases flow and communicate this to a controller which controls the power supplied to the heating apparatus with respect to information regarding the characteristic of the gases flow. A structure partially encloses the humidification chamber and allows energy loss through a wall of the humidification chamber. The humidification chamber may have features to promote heat loss through the wall of the chamber.

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