Articles: closed-circuit-anesthesia.
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Comparative Study
A practical rule for optimal flows for xenon anaesthesia in a semi-closed anaesthesia circuit.
Stable haemodynamics and its cardioprotective and neuroprotective properties favour xenon as an ideal but expensive anaesthetic agent. The aim of this study was to optimize a semi-closed anaesthesia circuit for xenon anaesthesia with respect to economics and patient safety. ⋯ The current study showed that, by optimization of the electronic regulation of the wash-in procedure for xenon anaesthesia, the consumption of the valuable gas can be reduced by up to 75% in a semi-closed circuit. The additional maintenance of anaesthesia under low flow conditions by coupling the xenon flow to the oxygen consumption is the most effective way to technically reduce the amount of xenon needed for anaesthesia.
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Case Reports
[Cleft in carbon dioxide absorber. Intraoperative problems with ventilation due to a leak in the breathing circuit].
In the case presented problems with mechanical and manual ventilation of a patient occurred during the operation. Prior to this endotracheal intubation had been performed without difficulty and the respirator had passed all system checks. A leakage in the recently changed carbon dioxide absorber could be detected which had been accidentally dropped and damaged internally.
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J Clin Monit Comput · Apr 2010
Case ReportsLeak in the breathing circuit: CO2 absorber and human error.
A couple of reports in literature have mentioned CO2 absorbers to be the cause for breathing circuit leak during anesthesia. Defective canister, failure to close the absorber chamber and overfilling of the chamber with sodalime were the problems in these reports. Among these, the last two are reports of human error resulting in problems. We report a case where despite taking precautions in this regard, we experienced a significant leak in the system due to a problem with the CO2 absorber, secondary to human error.
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Anesthesia and analgesia · Mar 2010
Detection of carbon monoxide during routine anesthetics in infants and children.
Carbon monoxide (CO) can be produced in the anesthesia circuit when inhaled anesthetics are degraded by dried carbon dioxide absorbent and exhaled CO can potentially be rebreathed during low-flow anesthesia. Exposure to low concentrations of CO (12.5 ppm) can cause neurotoxicity in the developing brain and may lead to neurodevelopmental impairment. In this study, we aimed to quantify the amount of CO present within a circle system breathing circuit during general endotracheal anesthesia in infants and children with fresh strong metal alkali carbon dioxide absorbent and define the variables associated with the levels detected. ⋯ CO was detected routinely during general anesthesia in infants and children when FGF:(.)VE was <1. Peak CO levels measured in the anesthesia breathing circuit were in the range thought to impair the developing brain. Further study is required to identify the source of CO detected (CO produced by degradation of volatile anesthetic versus rebreathing CO from endogenous sources or both). However, these findings suggest that avoidance of low-flow anesthesia will prevent rebreathing of exhaled CO, and use of carbon dioxide absorbents that lack strong metal hydroxide could limit inspired CO if detection was attributable to degradation of volatile anesthetic.