An additive gas delivery apparatus for delivery of additive gas to inspirational gas can be set to deliver the additive gas according to a dosing setting in normal therapy, and can be set to deliver according to a backup dosing setting in response disruption of signals representing data for controlling the delivery of additive gas according to the dosing setting in normal therapy. An additive gas delivery apparatus has an inlet for the additive gas and an integrated inlet for gas for oxygenating the patient that are connected to a backup line to mix the additive gas and gas for oxygenating the patient to a set concentration of additive gas in the gas mixture at an integrated backup outlet of the additive gas delivery apparatus.

Systems and methods are provided for detecting and sequestering waste anesthetic gases released by an anesthetic vaporizer. In one embodiment, a method for an anesthetic vaporizer installed in an anesthesia machine includes detecting an emission of waste anesthetic gases (WAGs) from the anesthetic vaporizer, and responsive to detecting the emission of WAGs, performing at least one of scavenging the WAGs and outputting an alert.

An apparatus and method for supplying anesthetic agent to an anesthesia system. The system is connecting detachably with at least two such apparatuses. The apparatus includes a storage volume for a liquid anesthetic agent and a space for evaporating the liquid agent. The apparatus also includes a gas inlet port for receiving a fresh gas for mixing with evaporated agent and a gas outlet port for conducting the gas mixture including evaporated agent to the system. The apparatus also includes a logic circuit for controlling anesthetic agent supply and an apparatus signal connector to exchange information. The apparatus signal connector includes at least one first apparatus contact for receiving from the system a signal indicating whether anesthetic agent supply is allowed or prevented, and a second apparatus contact to indicate that this apparatus is configured to supply anesthetic agent.

The invention concerns a cartridge for an inhalation device for delivering anaesthetic to a human or animal wherein anaesthetic in the cartridge is dispersed in an anaesthetic control release medium; an inhalation device for use with the cartridge and a formulation including at least one selected anaesthetic and anaesthetic control release medium.

Start-up protocols for a device and method for administering NO is described.

A diagnostic device is disclosed for characterisation of particles from a patient’s airways, such as a lung, when ventilated by a ventilator, and/or for control thereof, comprising a particle detecting unit configured to be connected to a conduit for passing expiration fluid from said patient, for obtaining data related to particles being exhaled from said patent’s airways.

The present invention pertains to a device (1) for ventilating a patient, including an invasive mechanical ventilator (2) for periodically providing a breathing gas to an invasive patient interface (20), wherein a gas injector (4) for injecting nitric oxide supplied by a source of nitric oxide (3) into the breathing gas supplied by the invasive mechanical ventilator (2) is provided.

A method of drying an anesthesia breathing system includes removing a CO.sub.2 absorber from the anesthesia breathing system, when the CO.sub.2 absorber is connected to an absorber inlet port and an absorber outlet port. The method further includes moving a bag-to-vent flow diverter to an intermediate position so as to simultaneously open both a bag channel and a ventilator channel, and connecting an inspiratory port and an expiratory port of the anesthesia breathing system together. A dry gas source is connected to an absorber outlet channel, and then a dry gas flow is provided through the bag channel and the ventilator channel so as to dry out moisture from a bag circuit and a ventilator circuit of the anesthesia breathing system.

A fluid delivery system provides fluid, such as supplement oxygen, to a patient in response to inhalation. The fluid delivery system includes a valve assembly that is triggered by sensing onset of inspiration by measuring a change in temperature of air flow in a nasal or oral cannula, mask or helmet.

A data processing device is provided for an anesthesia device for feeding an intravenously administered hypnotic, a volatile hypnotic, and an opioid such that the volume flow can be adjusted. The device determines and standardizes the effective concentrations of the anesthetics. A pharmacokinetic model adds up the standardized concentrations of the hypnotics to a total hypnotic concentration. An isobole is calculated based on a coordinate plane with a total hypnotic concentration axis and an opioid concentration axis, as a function of the currently determined concentrations. The system displays a two-dimensional action diagram with the y-axis as an indicator of the total hypnotic concentration and the x-axis as an indicator of the standardized opioid concentration. The calculated standardized total hypnotic concentration and opioid concentration and the isoboles determined are displayed. The display is adapted to changes occurring in the isoboles determined in the course of time.