An automated EP analysis apparatus for monitoring, detecting and identifying changes (adverse or recovering) to a physiological system generating the analyzed EPs, wherein the apparatus is adapted to characterize and classify EPs and create alerts of changes (adverse or recovering) to the physiological systems generating the EPs if the acquired EP waveforms change significantly in latency, amplitude or morphology.

Devices for delivering a controlled concentration of an agent are provided. The device includes a reservoir for the agent and a flow control portion operably connected to the reservoir. The device also includes a valve for releasing the agent from the flow control portion and a pump for flowing air to mix with the agent released by the valve and for flowing the agent and air mixture out of the device. Methods of delivering a vaporized agent to a subject are also provided. The methods include storing a liquid agent in a reservoir of a device and flowing the agent into a flow control chamber to change the agent to a gas. The methods also include mixing the agent in gas form with air and flowing the agent and air mixture out of the device to be delivered to a subject.

The invention relates to a reusable device for CO2 removal, suitable for use in a breathing system, as part of an anaesthesia arrangement, and based on an electro-charging and discharging method. The invention is related to holders, containers and so-called canisters including any subparts of such devices and methods of operating used in an anaesthesia arrangement, wherein the CO2 removal takes place.

The invention relates to a reusable device for CO2 removal, suitable for use in a breathing system, as part of an anaesthesia arrangement, and based on an electro-charging and discharging method. The invention is related to holders, containers and so-called canisters including any subparts of such devices and methods of operating used in an anaesthesia arrangement, wherein the CO2 removal takes place.

A coated anesthetic container for an anesthetic dispenser includes an anesthetic tank, which is capable of receiving a liquid anesthetic (Nm), as well as a refill unit for refilling liquid anesthetic (Nm). The anesthetic tank includes a wall and a coating on the inner surface of the wall. A wall of the refill unit is connected in a fluid-tight manner to the wall of the anesthetic tank. A coating is applied at least to the inner surface of the wall of the anesthetic tank. This coating is made of an alloy of nickel and phosphorus. The nickel portion is in a range of 80 wt.% to 97 wt.%, and the phosphorus portion is in a range of 3 wt.% to 15 wt.%. A process is provided for manufacturing such an anesthetic container.

An arrangement and a process filter out at least one gas from a gas mixture. A filter unit (4) of the filter arrangement comprises an inlet and an outlet and is adapted to filter the gas out of the gas mixture while the gas mixture flows through the filter unit (4). The filter unit (4) takes up the gas and heats up in the process. A filter temperature sensor (46, 46.2) of the filter arrangement is adapted to measure at least once an indicator of the temperature in a first measuring area (MP, MP.2) inside the filter unit (4). Depending on the measured temperature, a message is generated and output in a form perceptible by a human being. This message includes information about the current state of the filter unit (4).

A process for operating a ventilator (12) and a ventilator (12) operating according to the process are provided. A pressure target value (p.sub.z) is determined during a phase of exhalation (48) as a function of a compliance (C) determined in relation to the lungs (14) of a patient being ventilated by means of the ventilator (12).

A process for operating a ventilator (12) and a ventilator (12) operating according to the process are provided. A pressure target value (p.sub.z) is determined during a phase of exhalation (48) as a function of a compliance (C) determined in relation to the lungs (14) of a patient being ventilated by means of the ventilator (12).

Disclosed is a respirator which comprises an electronic control device and a pneumatic main line in which the following are connected pneumatically: a respiratory gas source, a valve, a mixing chamber, a gas-dosing unit, and a supply line. The gas-dosing unit is configured to convey external air and/or oxygen and/or anesthetic gas into the mixing chamber, the respiratory gas source is configured to deliver respiratory gas to the supply line, the mixing chamber is configured to make available respiratory gas, the supply line is configured to supply the patient with respiratory gas, and the valve is configured to at least temporarily reduce a stream of respiratory gas to a patient.

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.