A respiratory treatment apparatus configured to provide a flow of breathable gas to a patient, including a breathable air outlet, an outside air inlet, and an pneumatic block module, wherein the pneumatic block module includes: a volute assembly including an inlet air passage, a mount for a blower and an outlet air passage; the blower being mounted in the mount such that an impeller of the blower is in a flow passage connecting the inlet air passage and the outlet air passage; a casing enclosing the volute assembly, wherein air passages within the casing connect air ports on the volute assembly, wherein the inlet air passage of the volute assembly is in fluid communication with the outside air inlet and the outlet air passage of the volute assembly is in fluid communication with the air outlet.

A high flow therapy system for delivering heated and humidified respiratory gas to an airway of a patient, the system including 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 pressurized respiratory gas is controlled by a microprocessor.

A multifunctional ventilator interface for selectively providing ventilation and continuous oxygen therapy to a patient includes tubing defining a high-pressure gas lumen, a low-pressure gas lumen, and a pressure sensing lumen, a manifold housing defining a gas pathway, a jet pump housing coupled to the manifold housing and defining an entrainment port, a sleeve rotatably engaged to the jet pump housing, and a jet nozzle defining high- and low-pressure jet nozzle outlet ports operative to introduce gas from the high- and low-pressure gas lumens into the gas pathway. The sleeve includes first and second windows selectively alignable with the entrainment port by rotation of the sleeve, the first window configured to allow ambient air to flow into the entrainment port when at least partially aligned therewith, the second window being covered by a one-way valve configured to prevent ambient air from flowing into the entrainment port but to allow exhalation out of the entrainment port when the second window is at least partially aligned therewith.

A gas delivery conduit adapted for fluidly connecting to a respiratory gases delivery system in a high flow therapy system, the gas delivery conduit includes a first connector adapted for connecting to the respiratory gases delivery system, a second connector adapted for connecting to a fitting of a patient interface, tubing fluidly connecting the first connector to the second connector where the first connector has a gas inlet adapted to receive the supplied respiratory gas, one of electrical contacts and temperature contacts integrated into the first connector. The gas delivery conduit further can include a sensing conduit integrated into the gas delivery conduit, where the first connector of the gas delivery conduit is adapted to allow the user to couple the first connector with the respiratory gases delivery system in a single motion.

A connector having a connector body with an inlet and an outlet defining a gas flow passage therebetween. The connector body has an overlap portion that is configured to overlap with a portion of a second connector when connected. An access passage extends through the overlap portion to the gas flow passage.

A lighted air supply delivery assembly for use in delivering air to a patient is described herein. The lighted air supply delivery assembly includes an air/light connection tubing coupled between an oxygen concentrator and a patient oxygen delivery. The air/light connection tubing defines an airflow chamber for delivering a flow of oxygenated air from the oxygen concentrator to the patient oxygen delivery assembly, and includes one or more optical fibers positioned within the airflow chamber. A fiber-optic light engine coupled to the one or more optical fibers. A controller is coupled to the fiber-optic light engine and includes a processor programmed to execute algorithm steps of operating the fiber-optic light engine to display a light visible through the air/light connection tubing via the one or more optical fibers.

A shroud for a mask system includes a retaining portion structured to retain a frame, a pair of upper headgear connectors each including an elongated arm and a slot at the free end of the arm adapted to receive a headgear strap, and a pair of lower headgear connectors each adapted to attach to a headgear strap. The retaining portion, the upper headgear connectors, and the lower headgear connectors are integrally formed as a one piece structure.

A gas sensor kit includes a gas sensor that measures a gas concentration of an exhalation gas of a subject, a gas introduction part that introduces the exhalation gas of the subject to the gas sensor and a gas supply unit that supplies a therapeutic gas to the subject. In the gas sensor kit, the gas supply unit includes a flow rate adjusting part that adjusts flow rate of the therapeutic gas.

A medical tube transports gases to and/or from a patient. The medical tube includes a bead wrapped around a longitudinal axis of the medical tube. The bead forms a first portion of a lumen wall of the medical tube. The medical tube also includes a film wrapped around the longitudinal axis of the medical tube. A first portion of the film overlies the bead, and a second portion of the film forms a second portion of the lumen wall. The lumen wall, formed by the bead and the second portion of the film forms a substantially smooth bore. The medical tube can be reusable or reprocessable.

The control-monitor, used in combination with a percussive ventilation breathing head and internal reciprocating injector shuttle, includes in a casing a generator, sensory pulse amplitude, frequency and MAP modules and a gas amplitude and pulsatile frequency control knobs. First and second AMP control indicia include a bent conical AMP indicia (a wide span indicating greater amplitude, a narrow span indicating lesser amplitude) and a single waveform with an adjacent double-headed arrow vertical line. First and second F control indicia include a bent conical F indicia (a wide span indicating greater F and a narrow span indicating lesser F) and multiple waveforms with an adjacent double-headed arrow horizontal line.