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Journal of Clinical Monitoring and Computing

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22-03-2022 | Anesthetics | Original Research

Prospective validation of gas man simulations of sevoflurane in O₂/air over a wide fresh gas flow range

Authors: Esther Candries, Andre M. De Wolf, Jan F. A. Hendrickx

Published in: Journal of Clinical Monitoring and Computing | Issue 6/2022

Abstract

The use of inhaled anesthetics has come under increased scrutiny because of their environmental effects. This has led to a shift where sevoflurane in O₂/air has become the predominant gas mixture to maintain anesthesia. To further reduce environmental impact, lower fresh gas flows (FGF) should be used. An accurate model of sevoflurane consumption allows us to assess and quantify the impact of the effects of lowering FGFs. This study therefore tested the accuracy of the Gas Man® model by determining its ability to predict end-expired sevoflurane concentrations (F_ETsevo) in patients using a protocol spanning a wide range of FGF and vaporizer settings. After IRB approval, 28 ASA I-II patients undergoing a gynecologic or urologic procedure under general endotracheal anesthesia were enrolled. Anesthesia was maintained with sevoflurane in O₂/air, delivered via a Zeus or FLOW-i workstation (14 patients each). Every fifteen min, FGF was changed to randomly selected values ranging from 0.2 to 6 L/min while the sevoflurane vaporizer setting was left at the discretion of the anesthesiologist. The F_ETsevo was collected every min for 1 h. For each patient, a Gas Man® simulation was run using patient weight and the same FGF, vaporizer and minute ventilation settings used during the procedure. For cardiac output, the Gas Man default setting was used (= Brody formula). Gas Man®’s performance was assessed by comparing measured with Gas Man® predicted F_ETsevo using linear regression and Varvel’s criteria [median performance error (MDPE), median absolute performance error (MDAPE), and divergence]. Additional analysis included separating performance for the wash-in (0–15 min) and maintenance phase (15–60 min). For the FLOW-i, MDPE, MDAPE and divergence were 1% [− 6, 8], 7% [3, 15] and − 0.96%/h [− 1.14, − 0.88], respectively. During the first 15 min, MDPE and MDAPE were 18% [1, 51] and 21% [8, 51], respectively, and during the last 45 min 0% [− 7, 5] and 6% [2, 10], respectively. For the Zeus, MDPE, MDAPE and divergence were 0% [− 5, 8], 6% [3, 12] and − 0.57%/h [− 0.85, − 0.16], respectively. During the first 15 min, MDPE and MDAPE were 7% [− 6, 28] and 13% [6, 32], respectively, and during the last 45 min − 1% [− 5, 5] and 5% [2, 9], respectively. In conclusion, Gas Man® predicts F_ETsevo in O₂/air in adults over a wide range of FGF and vaporizer settings using different workstations with both MDPE and MDAPE < 10% during the first hour of anesthesia, with better relative performance for simulating maintenance than wash-in. In the authors’ opinion, this degree of performance suffices for Gas Man® to be used to quantify the environmental impact of FGF reduction in real life practice of the wash-in and maintenance period combined.

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Title: Prospective validation of gas man simulations of sevoflurane in O2/air over a wide fresh gas flow range
Authors: Esther Candries
Andre M. De Wolf
Jan F. A. Hendrickx
Publication date: 22-03-2022
Publisher: Springer Netherlands
Keywords: Anesthetics
Sevoflurane
Anesthetics
Desflurane
Published in: Journal of Clinical Monitoring and Computing / Issue 6/2022
Print ISSN: 1387-1307
Electronic ISSN: 1573-2614
DOI: https://doi.org/10.1007/s10877-022-00842-0

At a glance: The STEP trials

Springer Medicine

Prospective validation of gas man simulations of sevoflurane in O₂/air over a wide fresh gas flow range

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

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