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.

Introduced here is a self-contained face mask system with an automated liquid-droplet dispensing mechanism (ADM) for humidification. The enclosure of the self-contained mask system can be comprised of one or more layers of breathable fabric adapted to flexibly conform to the face of a user when worn to form a cavity that is adjacent the nostrils and mouth. The ADM of the face mask system can be comprised of a reservoir in which liquid is stored, a respiratory cycle detector, a timer and controller, and a droplet dispenser that controllably dispenses droplets of the liquid from the reservoir into the cavity for inhalation by the user. The ADM can be contained entirely within the face mask enclosure or supported on the surface of the face mask enclosure such that the self-contained mask system, when worn by a user, can be supported entirely by the head and neck of the user.

A positive air pressure delivery device includes a housing having an inhalation inlet, an inhalation outlet, and an interior cavity in fluid communication with the inhalation inlet and outlet. A pressurized fluid inlet includes an outlet orifice in fluid communication with the interior cavity between the inhalation inlet and outlet. A sound reducer baffle has a convex dome surface positioned downstream of and facing the outlet orifice in a spaced apart relationship therewith. One embodiment of the housings includes a body, an end cap and a baffle insert. In various embodiments, the positive air pressure delivery device may be used in combination with other therapy devices, including an OPEP and pressure indicator. A kit and method of using the device are also provided.

Described herein are methods, devices and systems for respiratory therapy delivered by a therapy vest. A therapy vest is provided in which an independent body fitting function is provided by use of a body fit layer or compartment(s). The body fit layer or compartment(s) may be controlled independently from the therapy layer or compartment(s), such that the fit of the therapy vest is placed on more equal footing with the therapy delivering components of the therapy vest. Other examples are disclosed and claimed.

An automatic control system for a tracheobronchial-air stimulation device intended to be connected to a subject. The stimulation device is configured to generate a set of negative pressure pulses during a relaxed exhalation of the subject. Also, a method for automatically controlling the tracheobronchial-air stimulation device, and a computer program and non-transitory computer readable medium, each of which comprise instructions for implementation of the method.

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 ventilation system that includes a pressure source, a pneumatic path configured to receive gas from the pressure source and comprising a first pneumatic component coupled to a second pneumatic component. The first pneumatic component includes a first electrical conductor including a first electrical component having a first electrical characteristic. The second pneumatic component comprises a second electrical conductor including a second electrical component having a second electrical characteristic. The first electrical conductor is electrically connected with the second electrical conductor in an electric path. The system performs operations including determining a continuity of the electrical path; displaying a notification regarding the continuity of the electrical path; detecting the unique electrical characteristic of the electric path; and determining a pneumatic characteristic of the pneumatic path.

A portable oscillator of positive expiratory pressure having capability for oscillating indication, the portable oscillator of positive expiratory pressure comprises a shell, an oscillation element and an indicator element; the shell has a pressurized cavity, the oscillation element has a valve to close the pressurized cavity, the indicator element is used to respond an oscillating state of the oscillation element and a static state of the oscillation element; wherein the shell and the oscillation element are respectively provided with a first magnetic element and a second magnetic element; when an expiratory airflow through the pressurized cavity drives the oscillation element to rotate, the valve will separate from the pressurized cavity to release the pressure, a distance between the first magnetic element and the second magnetic element is simultaneously shortened to quickly respond to a repulsive force which is generated between the same poles, and therefore the oscillation element can be returned to an original position; when the valve recloses the pressurized cavity, the pressurized cavity will produce an exhalation resistance.

A gas turbine engine with a rotor comprising a turbine and compressor, mounted in a housing surrounding the rotor. The rotor rotates on one or more hydro bearings, the profiles of the outer surface of the rotor and the inner surface of the housing generating the hydro bearing(s). A combustion chamber is formed within the housing, and the combustion products of the fuel/air mixture are directed from the combustion chamber to the turbine. The housing and rotor are formed by an additive manufacturing process in a single procedure, with the rotor enclosed within the housing, and unsupported by any mechanical connections. A gas turbine respiratory ventilator system is described using a compressed oxygen flow to power the turbine which rotates the centrifugal blower for generating the air flow for respiration of the patient. The oxygen exhausted from the turbine can then be used to supplement the air flow.

A respiratory system, primarily to provide a mechanical insufflation/exsufflation therapy, may include a first pressure generating source, a second pressure generating source and a primary valve to switch between insufflation/positive pressure flow and exsufflation/negative pressure flow, and to generate oscillations alongside either of these cycles. The respiratory system can optionally employ a secondary valve either on a fluidic path of the first pressure generating source or on a fluidic path of the second pressure generating source. An interfacing assembly acts as a fluidic conduit between the pressure generating sources and the patient. A control unit is configured to generate required pressurized flow and oscillations as per the user settings. The aforesaid valves can be manipulated into multiple orientations/positions, which are aligned and/or adjusted with respect to the respective pressure generating sources as per the therapy requirements.