A respiratory ventilator device is described herein. The respiratory ventilator device includes an inhaled air assembly and a pneumatic compressed air assembly. The inhaled air assembly includes an injector diaphragm housing including a flexible silicone rubber diaphragm dividing an interior volume into an inhalation air chamber containing inhalation air and a compressed air chamber for containing compressed air. The pneumatic compressed air assembly operates in a compression phase delivering compressed air into the compressed air chamber to inflate the flexible silicone rubber diaphragm to reduce a volume of the inhalation air chamber and channel the inhalation air to a patient respiratory circuit, and operates in an expansion phase removing compressed air from the compressed air chamber to deflate the flexible silicone rubber diaphragm to increase the volume of the inhalation air chamber and receive the inhalation air from the supply of oxygenated air.

A ventilator system for providing respiratory support in cases of acute respiratory failure or severe trauma is described. The ventilator system has a ventilator and a tubing system. The system is characterized in that the ventilator has a continuous bleed valve configured to be open to air flow from the blower at all times when the blower is operating during both inspiration and expiration; thereby providing a minimal amount of pressure within a patient's lungs at the end of each exhalation—positive end expiratory pressure (PEEP). In an embodiment of the invention the system comprises a manifold block configured to hold the main operating elements of the ventilator.

A radial fan (1) is provided with a motor (2) and a fan housing, an outer part (4) and an inner part (5) that form a spiral-like pressure chamber (D). A pressure connector (33) which forms an outlet (44) of the radial fan (1) is arranged on the outer part. The fan housing is equipped with a fan wheel (3) which is arranged on a shaft (7) connected to the motor (2), wherein an annular flow divider (8) which surrounds the fan wheel (3) is arranged adjacently to the fan wheel (3) in a radial direction. The flow divider together with the fan housing forming a diffuser (9), which transitions directly into the pressure chamber (D), about the fan wheel (3).

A respiratory device for providing respiratory support to a patient. The device includes an expandable bag portion and a connection member in fluid communication with the expandable bag portion. The expandable bag portion includes an air intake valve and has an adjustable predetermined tidal volume. The connection member includes a positive end expiratory pressure (PEEP) valve, a PEEP controller configured to control the pressure of the PEEP valve, a two-way valve configured to allow air to move from the expandable bag portion in a first direction and through the PEEP valve in an opposing direction, a pressure relief valve configured to vent excess pressure from the connection member to an external environment, and a patient breathing interface.

An oxygen concentrator includes one or more adsorbent sieve beds operable to remove nitrogen from air to produce concentrated oxygen gas at respective outlets thereof, a product tank fluidly coupled to the respective outlets of the sieve bed(s), a compressor operable to pressurize ambient air, one or more sieve bed flow paths from the compressor to respective inlets of the sieve bed(s), a bypass flow path from the compressor to the product tank that bypasses the sieve bed(s), and a valve unit operable to selectively allow flow of pressurized ambient air from the compressor along the one or more sieve bed flow paths and along the bypass flow path in response to a control signal. The valve unit may be controlled in response to a command issued by a ventilator based on a calculated or estimated total flow of gas and entrained air or % FiO.sub.2 of a patient.

Architectures for production of nitric oxide (NO) include systems and methods for generating NO having one or more plasma chambers configured to ionize a reactant gas to generate a plasma for producing a product gas containing NO using a flow of the reactant gas through one or more plasma chambers; a controller configured to regulate the amount of nitric oxide in the product gas using one or more parameters as an input to the controller, one or more parameters including information from a plurality of sensors configured to collect information relating to at least one of the reactant gas, the product gas, and a medical gas into which product gas flows; and a flow divider configured to divide a product gas flow from the plasma chamber into a first product gas flow to provide a variable flow to a patient inspiratory flow and a second product gas flow.

A respiratory device for providing respiratory support to a patient. The device includes an expandable bag portion and a connection member in fluid communication with the expandable bag portion. The expandable bag portion includes an air intake valve and has an adjustable predetermined tidal volume. The connection member includes a positive end expiratory pressure (PEEP) valve, a PEEP controller configured to control the pressure of the PEEP valve, a two-way valve configured to allow air to move from the expandable bag portion in a first direction and through the PEEP valve in an opposing direction, a pressure relief valve configured to vent excess pressure from the connection member to an external environment, and a patient breathing interface.

A cuff pressure controller device (100) is connected to a foregoing cuff (10) via an air supply tube (125). The cuff pressure controller device (100) includes a controller unit (111), a cuff pressure detector unit (113), a driver circuit (119), a piezoelectric pump (101), a check valve (121), and a release valve (122). The cuff pressure detector unit (113) detects the cuff pressure of the cuff (10). The driver circuit (119) drives the piezoelectric pump (101) at a drive frequency of 20 kHz or higher. The controller unit (111) controls the cuff pressure detector unit (113), the driver circuit (119), and the release valve (122) in such a way that the cuff pressure stays within a predetermined range based on detection results of the cuff pressure detector unit (113) and the like.

A breathing assistance apparatus includes an inner volumetric member pressurizable from a first pressure to a second pressure and an outer volumetric member surrounding at least a portion of the inner expandable volumetric member. The inner volumetric member pressurizes the outer volumetric member as the inner volumetric member is pressurized from the first pressure to the second pressure. In another embodiment, a breathing assistance apparatus includes exhalation and inhalation chambers with respective biasing members providing for the exhalation chamber to apply a pressure to the inhalation chamber and thereby provide assisted inhalation. Methods for assisting breathing are also provided.

A device for measuring a concentration of a component in a target sample includes a flow chamber with a first channel that receives a reference sample having a known concentration of the component. The flow chamber also includes a second channel that receives the target sample having an unknown concentration of the component. A pump operates to pump the reference sample and the target sample at a same volume flow rate through the first and second channels, respectively. A thermal mass flow meter measures a thermal conductivity of the reference sample, a thermal conductivity of the target sample, or both.