British Journal of Anaesthesia

BJA Advance Access published online on November 19, 2007
British Journal of Anaesthesia, doi:10.1093/bja/aem311

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Effects of carbon dioxide absorbent cooling and temperature gradient reduction on water condensation in the anaesthesia circuit

G. Hirabayashi^*, H. Uchino, T. Joko, H. Kaneko and N. Ishii

Department of Anesthesiology, Hachioji Medical Center, Tokyo Medical University, 1163 Tatemachi, Hachioji, Tokyo 193-0998, Japan

^* Corresponding author. E-mail: goh{at}tokyo-med.ac.jp

Background: Large quantities of water condensation occur in the anaesthesia circuit during low-flow anaesthesia. We hypothesized that cooling of the CO₂ absorbent would prevent water condensation.

Methods: To cool CO₂ absorbent efficiently, we constructed a novel temperature gradient reduction (TGR) canister, which was cooled by a blower. Experiments were divided into three groups: the conventional canister group (control group, n=6), the TGR canister without cooling group (TGR group, n=6), and the TGR canister with cooling group (TGR cooling group, n=6). One kilogramme of CO₂ absorbent was placed into the canister. The anaesthetic ventilator was connected to a 3 litre bag and 300 ml min^–1 of CO₂ was introduced. About 500 ml min^–1 of oxygen was used as fresh gas. The anaesthetic ventilator was set at a ventilatory frequency of 12 bpm, and tidal volume was adjusted to 700 ml.

Results: The longevity of the CO₂ absorbent was 437 (SD 7.8) min in the control group, 564 (13.8) min in the TGR group (P<0.001 vs control), and 501 (5.8) min in the TGR cooling group (P<0.001 vs control, TGR). Total water condensation in the anaesthesia circuit was 215 (9.4) mg min^–1 in the control group, 223 (9.7) mg min^–1 in the TGR group, and 47.7 (5.7) mg min^–1 in the TGR cooling group (P<0.001 vs control, TGR).

Conclusions: TGR of CO₂ absorbent with cooling is a useful and simple method to reduce water condensation in the anaesthesia circuit in low-flow anaesthesia, with a little increase in the longevity of the CO₂ absorbent.

Keywords: equipment, absorbers; equipment, anaesthesia machine; humidification; monitoring, carbon dioxide; ventilation, failure; ventilation, fresh gas flow

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Online ISSN 1471-6771 - Print ISSN 0007-0912

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