A gas conduit for respiratory apparatus includes a lumen for passage of a breathable gas to a patient and a flexible conduit wall surrounding the lumen. The flexible conduit wall has a humidification apparatus for delivering water vapour into the gas passing through the lumen.

A humidifier for humidifying a flow of pressurized breathable gas to be delivered to a patient includes a dock and a humidification tub. The dock includes a device compartment that is configured to at least partially removably receive an RPT device that is configured to supply the flow of pressurized breathable gas. The dock also includes a humidification compartment that is fluidly connected to the device compartment. The humidification tub is configured to contain a supply of water and is at least partially removably received within the humidification compartment so that, in an operational configuration, the humidification tub is arranged to receive the flow of pressurized breathable gas and output the flow of pressurized breathable gas with increased humidity. The dock also includes a heater fixed to the humidification tub. The heater is configured to heat the supply of water.

A respiratory mask assembly includes a frame having a channel and a cushioning element including a clip portion adapted for interference seal and retention in the channel. The cushioning element includes an interfacing portion constructed from foam and having a wider width than the clip portion.

A process for monitoring a measuring system (110) for mechanical ventilation of a patient (20) is carried out while a fluid connection (40) is established between the patient (20) and a medical device (100). A gas sample is suctioned from the fluid connection (40) and is sent through a gas sensor fluid-guiding unit (52) to a gas sensor array (50). A time curve of the CO2 concentration and O2 concentration in the suctioned gas sample are determined. A concentration change curve of the change over time of the CO2 concentration and the O2 concentration are calculated. A search is made for a time period in which the two concentration change curves continuously have the same sign. Upon detecting such a time period it is checked whether a predefined first leak criterion is met. When this is the case, an indication of a leak (L) is detected.

Technologies (e.g., devices, systems and methods) for sanitizing positive airway pressure (PAP) systems are described. In some embodiments, the technologies include a PAP delivery system comprising a hose and a PAP mask, a positive pressure supply system configured to generate a flow of pressurized air which is delivered to a user through the hose to the PAP mask of the PAP delivery system, a sanitizing system configured to sanitize one or more components of the self-sanitizing PAP system, and a PAP base unit housing, wherein one or more components of the positive pressure supply system and the sanitizing system are disposed at least partially within the PAP base unit housing.

An apparatus comprises a centrifugal fan having an inlet and outlet, the fan receives ventilation air at the inlet and provides the ventilation air at an adjustable pressure at the outlet, a first respiration line with a first end connected to the inlet and a second end for receiving inhalation air, a second respiration line having a first end connected to the outlet and a second end for coupling a filter and a ventilation mask, the second respiration line having a sensor, to measure a flow parameter in the second respiration line, and a device for controlling the fan according to an output signal of the sensor, the fan and second respiration lines forming a continuous bidirectional flow path, the adjustable ventilation pressure at the outlet comprises an inhalation or an exhalation pressure less than or equal to the inhalation pressure, and the second respiration line has an air filter.

Ventilator system with multiple inspiratory lumens is provided. The inspiratory lumens are configured so that separate inspiratory lumens provide inspiratory gas mixtures to separate portions of a patient's airways, for instance to separate lungs and/or bronchi. The ventilator system can include one or more expiratory lumens to evacuate expiratory gases from airways. The use of separate inspiratory lumen(s), with expiratory lumen(s), allows for functional separation of structural portions of the lungs, and maintenance of continuous or almost continuous flow through at least part of respiratory cycle via inspiratory and expiratory lumens. This can further reduce dead space and clear suspended therein diseases causative agents with improvement in outcomes, reduce risk of cross-contamination or cross-infection between different parts of airways, for example such as cross-infection from one lung lobe to another lobe or. The ventilator system allows for independent titration of PEEP, pCO.sub.2 and pO.sub.2 with no need for permissive hypercapnia.

A patient module (10) is intended for use when ventilating a patient with a pressure source (24) that can be fluidically coupled via the patient module (10) to a patient interface (26), which can be connected to the airways of a patient. The patient module (10) includes a housing (12) and a valve section (14) in the housing (12) as well as an HME filter (30) spaced apart from the valve section (14). The HME filter (30) is located upstream of the valve section (14) in relation to an expiratory volume flow, so that the HME filter (30) divides an interior of the housing (12) into a dry area and an area coming into contact with the moisture carried along by the exhaled breathing gas. The valve section (14) is located in the dry area. A process for operating the patient module (10) includes calibration steps.

Systems and methods are provided for delivering anesthetic agent to a patient. In one embodiment, an anesthetic vaporizer includes a vaporizing chamber configured to hold a liquid anesthetic agent, and an inductive heating element positioned exterior to the vaporizing chamber and housed within a gas-tight barrier, the inductive heating element operated to selectively heat a target.

Technologies (e.g., devices, systems and methods) for sanitizing positive airway pressure (PAP) systems are described. In some embodiments, the technologies include a PAP delivery system comprising a hose and a PAP mask, a positive pressure supply system configured to generate a flow of pressurized air which is delivered to a user through the hose to the PAP mask of the PAP delivery system, a sanitizing system configured to sanitize one or more components of the self-sanitizing PAP system, and a PAP base unit housing, wherein one or more components of the positive pressure supply system and the sanitizing system are disposed at least partially within the PAP base unit housing.