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.

A water electrolysis device for generating hydrogen gas includes a case, a power supplying unit, and an ion-exchange membrane electrolyzer. The case has a containing space including a bottom space and a top space. The bottom space is larger than the top space. The power supplying unit is configured in the bottom space for supplying power to operate the water electrolysis device. The ion-exchange membrane electrolyzer includes an ion-exchange membrane and a cathode, and the cathode generates hydrogen gas during which the ion-exchange membrane electrolyzer electrolyzes water.

An inhalation device for e.g., nicotine products which receives a user input regulating the amount of nicotine the user wants to receive. Once the selected amount has been delivered to the user, the device shuts off its atomizer to conclude operation.

Disclosed is an NO supply device including a main gas circuit to convey an NO/N.sub.2 mixture to a main output orifice which is designed to supply the inspiratory branch of a medical ventilator; and a backup circuit including a backup NO circuit including a backup NO line which is supplied with NO/N.sub.2 mixture, and a backup O.sub.2 circuit includes a main O.sub.2 line which is connected fluidically to the backup NO line in order to form a common line in fluid communication with a secondary output which supplies an NO/N.sub.2/O.sub.2 mixture designed to supply a manual breathing bag.

Disclosed is an NO supply device including a main gas circuit with NO/N.sub.2 flowrate controller controlled by piloting unit, and a backup circuit including a backup NO circuit and a backup O.sub.2 circuit. The piloting unit are configured in particular to control the NO/N.sub.2 flowrate controller in such a way as to regulate the flowrate of NO/N.sub.2 mixture in the main gas circuit and to direct the gaseous flow obtained in a downstream portion of the backup NO circuit connecting to the backup O.sub.2 circuit in order to form a common backup line including a backup outlet.

A device and method for calibrating a delivery device includes providing a container A containing a nitrite, providing a container B containing an acid, releasing the contents of containers A and B, allowing the nitrite and acid to mix, waiting for a predetermined time, allowing air to combine with the mixture, and using NO and traces of NO.sub.2 to check and calibrate NO and NO.sub.2 sensors.

An anesthetic evaporator unit (2) with an anesthetic container (4) for receiving liquid anesthetic, with a gas line (6) with an open-pore, porous line wall (8) for guiding gas and for enriching the gas with anesthetic, and with an anesthetic-guiding wick (10), which extends from an interior space (12) of the anesthetic container (4) to the line wall (8) in order to supply the line wall (8) with anesthetic from the anesthetic container (4). The anesthetic evaporator unit (2) has a heater (14) for heating the gas line (6). A method for controlling the anesthetic evaporator unit (2) is also provided.

Systems and methods for nitric oxide (NO) generation systems are provided. In some embodiments, an NO generation system comprises at least one pair of electrodes configured to generate a product gas containing NO from a flow of a reactant gas. The electrodes have elongated surfaces such that a plasma produced is carried by the flow of the reactant gas and glides along the elongated surfaces from a first end towards a second end of the electrode pair. A controller is configured to regulate the amount of NO in the product gas by the at least one pair of electrodes using one or more parameters as an input to the controller. The one or more parameters include 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 the product gas flows.

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 nasal ventilation mask having one or more attachment ports located adjacent to and overlying an upper lip of a patient when worn.