Embodiments of the present invention provide systems and methods for delivering respiratory treatment to a patient. For example, a treatment system may include a mechanism for delivering a positive pressure breath to a patient, and one or more limb flow control assemblies which modulate gas flow to and from the patient. Exemplary treatment techniques are embodied in anesthesia machines, mechanical ventilators, and manual ventilators.

High flow therapy is used to treat Cheyne-Stokes respiration and other types of periodic respiration disorders by periodic application of high flow therapy, adjustment of high flow therapy flow rates and/or periodic additions of CO2 or O2 into the air flow provided to the patient.

A method of estimating a parameter indicative of respiratory flow of a patient being administered flow therapy, comprising: optionally administering a gas at a flow rate to the patient using a flow therapy apparatus with a patient interface, determining a terminal pressure in, at or proximate the outlet of the patient interface or in, at or proximate the nares of the patient, determining nasal RTF, determining a nasal flow parameter being or indicative of nasal flow based on the pressure and a nasal RTF, and optionally outputting the nasal flow parameter or parameter derived therefrom.

The disclosure relates to a method and respiratory system, comprising: a flow generator to provide a gas-flow to a patient, the gas flow comprising an oxygen fraction, and a controller configured to: receive input relating to oxygen fraction at a patient's nose and/or mouth, adjust the gas-flow flow rate based on the oxygen fraction at the patient's nose and/or mouth.

An oxygen concentration system may comprise a pressure sensor, a movement sensor, and a controller configured to use one or more pressure signals obtained from the pressure sensor and a movement signal obtained from the movement sensor to determine when to release a bolus of oxygen enriched air. In some implementations, the controller may adjust a trigger threshold based on an initial pressure signal obtained from the pressure sensor and the movement signal obtained from the movement sensor. In some implementations, the controller may adjust a pressure signal obtained from the pressure sensor based on the movement signal obtained from the movement sensor. In some implementations, the controller may detect a potential onset of inhalation from a pressure signal obtained from the pressure sensor and determine whether to verify the potential onset of inhalation based on the movement signal obtained from the movement sensor.

A ventilator system configured to switch between one or more invasive ventilation modes and one or more non-invasive ventilation modes is provided, the ventilator system comprising: an externally pressurized source of pre-mixed gas comprising air and oxygen; one or more inspiratory valves configured to deliver incoming pre-mixed gas to a patients breathing circuit; and one or more expiratory valves configured to remove outgoing gas from the patients breathing circuit; wherein in the one or more invasive ventilation modes, the inspiratory valves and the expiratory valves are configured to open and close to allow or prevent the passage of gas as needed in order to enforce a respiration cycle within the patient; and wherein in the one or more non-invasive ventilation modes, the inspiratory valves and the expiratory valves are kept open in order to allow the gas to pass freely through the system.

A fan unit that forms part of a gases supply unit used as part of a breathing assistance system for providing heated gases to a user. The fan has an impeller surrounded by an upwardly sloped surface to facilitate improved airflow performance under surge conditions.

The present disclosure provides for a control system for a flow therapy apparatus. The control system can control delivery of a fraction of delivered oxygen (FdO2) to a patient. The control system can maintain the FdO2 at a target level during a therapy session. The control system can automatically control an oxygen inlet valve in order to control the flow of oxygen to the patient.

A medical tube comprises a spirally wound bead forming a plurality of successive coils. Each of the plurality of successive coils has an internal diameter and an external diameter, and a spirally wound film extending between adjacent coils of the bead. The film is bonded at a first location on a surface of a first coil of the bead and at a second location on a surface of a second coil of the bead. The first coil is adjacent to the second coil and the first location and the second location are located between the internal diameters and external diameters of respective first and second adjacent coils. Together the spirally wound bead and spirally wound film form a conduit.

Embodiments of the present invention may exist as a machine for continuous positive airway pressure, otherwise known as a “CPAP machine” in the art. The CPAP machine of the present invention may comprise a casing and plurality of working parts, the working parts including but not limited to a blower fan, one or more batteries, and a circuit board. All of the working parts may be housed within the casing, which allows the CPAP machine to exist as one compact unit that can be easily worn by a user without use of a hose, tube, external wire, or other component used to connect a component of a CPAP machine to the portion of a CPAP machine that is worn on, over, or in front of a user's face.