A portable oxygen concentrator includes a compressor and a controller. The compressor includes a motor, at least one chamber, and at least one piston operably coupled to the motor and movable within the at least one chamber. In some embodiments, the controller is configured to: determine actual motor speeds for commutations steps of the motor during a first rotational cycle; determine an average motor speed during the first rotational cycle; determine a voltage pattern based at least on a comparison of the average motor speed during the first rotational cycle and the actual motor speeds for the commutation steps of the motor during the first rotational cycle; and cause the voltage pattern to be applied to the motor during a second rotational cycle to reduce differences between applied motor torque and variable torque load imparted by the at least one piston.

An ambulatory assist ventilation (AA V) apparatus and system are disclosed for the delivery of a respiratory gas to assist the spontaneous breathing effort of a patient with a breathing disorder. The AA V system includes a compressed respiratory gas source, a respiratory assist device for controlling respiratory gas flow to the patient, a patient circuit tubing and a low profile nasal interface device, which does not have a dead space or hollow area where CO2 can collect, for delivering the respiratory gas to the patient, wherein the nasal interface device is fluidly connected to the respiratory assist device via tubing for receiving the respiratory gas therefrom.

A gas valve system adapted for controlling the flow of a gas for a user is disclosed. The gas valve system comprises a housing, at least one sensor, one or more electronic and/or mechanical components for controlling the gas flow, and a manifold comprising one or more channels for guiding the gas between an input and an output of the gas valve system and to which the at least one sensor and one or more electronic and/or mechanical components can be coupled.

A pulsed oxygen delivery system is disclosed for a closed breathing environment, which includes a source of gaseous oxygen, a phase dilution type oronasal dispensing mask worn by a user in a closed breathing environment defined by a pressure suit, and a pulse control module for delivering a timed and metered bolus of oxygen from the source of gaseous oxygen to the oronasal dispensing mask upon inhalation by the user.

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.

A fluid delivery system provides fluid, such as supplement oxygen, to a patient in response to inhalation. The fluid delivery system includes a valve assembly that is triggered by sensing onset of inspiration by measuring a change in temperature of air flow in a nasal or oral cannula, mask or helmet.

Apparatus, such as a portable oxygen concentrator (100) or other device communicating therewith, may be configured, such as with a processor(s), to estimate a remaining capacity of a sieve bed of the concentrator. Such apparatus may be configured to access a parameter of a measured pressure-time characteristic of the sieve bed for a phase of a pressure swing adsorption cycle of the oxygen concentrator. The apparatus may be configured to access function(s) of the parameter of the pressure-time characteristic and operational characteristic(s) of the sieve bed. The apparatus may be configured to estimate the remaining capacity by applying the function(s) to the parameter of the measured pressure-time characteristic. Such an estimate may then serve as a basis for providing notification, such as on a display or by electronic messaging, to inform of remaining life of the sieve bed, or otherwise promote timely replacement of a depleting component.

The present invention relates to a nasal oxygen cannula, which has a simple and economic design that reduces drug wastage and allows the effective use time to be measured in order to effectively monitor oxygen therapy treatment in patients with spontaneous breathing. Structurally, the cannula is formed by a mechanical system that is only activated when it comes into physical contact with the patientís columella, and an electronic component that allows the real use time of the device to be measured by means of an electric actuator that triggers an electric pulse the moment the cannula is in place on the user.

Devices and methods are provided herein for sensing and monitoring of patient breathing during high flow respiratory therapy. A nasal cannula having a sensing lumen and remotely-located pressure sensor is provided herein for breath sensing that provides an accurate and clear signal while high flow rates of breathing gas are delivered from the nasal cannula. Condensation can be removed from the sensing lumen by applying a constant, pulsatile, or burst flow of purge gas. The breath sensing apparatus can be integrated in a respiratory system with a breathing gas source or can be packaged as a separate device capable of adapting to a variety of systems.

Systems and methods for increasing accuracy of the fraction of inspired oxygen (FiO2) in delivered breathing gases. In an aspect, the technology relates to a blower-based ventilation system. The system includes a blower; an oxygen flow valve; a processor; and memory storing instructions that, when executed by the processor causes the system to perform a set of operations. The set of operations include, based on a target oxygen concentration level, determining a target ambient air flow rate and a target oxygen flow rate; measuring a flow rate of ambient air generated by a blower; measuring a flow rate of oxygen from an oxygen flow valve; determining a synchronization error; and based on the synchronization error, adjusting operation of at least one of the blower or the oxygen flow valve.