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Correspondence  |   April 2014
Intraoperative High Inspired Oxygen Fraction: Are There Real Benefits?
Author Affiliations & Notes
  • (Accepted for publication November 19, 2013.)
    (Accepted for publication November 19, 2013.)×
Article Information
Correspondence
Correspondence   |   April 2014
Intraoperative High Inspired Oxygen Fraction: Are There Real Benefits?
Anesthesiology 04 2014, Vol.120, 1052-1053. doi:10.1097/ALN.0000000000000157
Anesthesiology 04 2014, Vol.120, 1052-1053. doi:10.1097/ALN.0000000000000157
To the Editor:
We read with interest the meta-analysis by Hovaguimian et al.1  on the effects of a high perioperative inspiratory oxygen fraction. The positive conclusions in terms of decreased risk of surgical site infection (SSI), weak prophylactic effect on nausea, and no increased risk of atelectasis raise several methodological concerns.
First, the preventive effect on SSI was reported for patients receiving prophylactic antibiotics although the observed difference was not statistically significant (upper 95% CI, 1.00). Moreover, the actual rates of patients receiving antibiotics were only reported in four of the nine trials,2–5  leaving the conclusion to be based on protocol information from five trials, and a separate analysis of antibiotics versus no antibiotics was omitted. The large body of evidence demonstrating no significant effect on SSI from perioperative hyperoxia to 1,966 patients for caesarean section was excluded from the current meta-analysis, because the intervention was delivered through nonrebreathing masks during neuraxial anesthesia,6  although such face masks are able to deliver a fraction of inspired oxygen (Fio2) greater than 0.60 inducing an adequate high-to-normal Fio2 ratio. The Evaluation of Nitrous Oxide In the Gas Mixture for Anaesthesia (ENIGMA) trial, favoring hyperoxia versus nitrous oxide to prevent SSI, was included without restrictions in the meta-analysis, suggesting that there is no difference between nitrous oxide and nitrogen in this context.5  However, a randomized trial of 197 patients7  receiving five different interventions, including a perioperative Fio2 of 0.80, was excluded because data could not be extracted. Data seem to be available, and the significantly increased risk of SSI in the intervention group in that study would further have challenged the primary conclusion of this meta-analysis.
Second, the mild beneficial effect of perioperative inspiratory hyperoxia on postoperative late nausea was the only one of six secondary outcomes that was statistically significant, suggesting that this finding may be due to chance rather than the intervention.
Third, although no significant differences were found as to the rates of pulmonary side effects, that outcome was not accurately defined and the adverse effects may be greatly underdiagnosed, because routine pulmonary examinations have not been performed in any of the large trials. Other harms were not assessed, but recently published data suggest increased long-term mortality with 80% oxygen.8  A positive risk–benefit ratio along with the administration of a high perioperative inspiratory oxygen fraction is therefore not evident.
The meta-analysis included trials at low as well as high risk of bias, and finally, the authors did not consider the risk of finding the nearly significant result by chance because of too few randomized patients, which might have tempered their conclusion. The meta-analysis presented by the authors—following the previously published meta-analyses—may only be regarded as an interim-analysis toward a conclusive answer. In a trial sequential analysis,9  it can be calculated that the diversity-adjusted required information size is 9,019 randomized patients for showing a 23% relative risk reduction (fig. 1), and there are thus no conclusive answer so far, as only 5,103 patients have actually been randomized.
Fig. 1.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1  Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1 Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
Fig. 1.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1  Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
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Competing Interests
All authors of this letter were members of the PROXI trial steering committee investigating 80% oxygen to prevent surgical site infection (JAMA 2009; 302:1543–50) and are also authors of an upcoming Cochrane review about the effects of high perioperative inspiratory oxygen fraction for adult surgical patients (Cochrane Database of Systematic Reviews 2010, Issue 12. Art. No.: CD008884. DOI:10.1002/14651858.CD008884).
Christian S. Meyhoff, M.D., Ph.D., Lars N. Jorgensen, M.D., D.M.Sc., Jørn Wetterslev, M.D., Ph.D., Lars S. Rasmussen, M.D., D.M.Sc. Copenhagen University Hospital, Herlev, Copenhagen, Denmark (C.S.M.). christianmeyhoff@gmail.com
References
Hovaguimian, F, Lysakowski, C, Elia, N, Tramèr, MR Effect of intraoperative high inspired oxygen fraction on surgical site infection, postoperative nausea and vomiting, and pulmonary function: Systematic review and meta-analysis of randomized controlled trials.. Anesthesiology. (2013). 119 303–16 [Article] [PubMed]
Pryor, KO, Fahey, TJIII, Lien, CA, Goldstein, PA Surgical site infection and the routine use of perioperative hyperoxia in a general surgical population: A randomized controlled trial.. JAMA. (2004). 291 79–87 [Article] [PubMed]
Meyhoff, CS, Wetterslev, J, Jorgensen, LN, Henneberg, SW, Høgdall, C, Lundvall, L, Svendsen, PE, Mollerup, H, Lunn, TH, Simonsen, I, Martinsen, KR, Pulawska, T, Bundgaard, L, Bugge, L, Hansen, EG, Riber, C, Gocht-Jensen, P, Walker, LR, Bendtsen, A, Johansson, G, Skovgaard, N, Heltø, K, Poukinski, A, Korshin, A, Walli, A, Bulut, M, Carlsson, PS, Rodt, SA, Lundbech, LB, Rask, H, Buch, N, Perdawid, SK, Reza, J, Jensen, KV, Carlsen, CG, Jensen, FS, Rasmussen, LS PROXI Trial Group, Effect of high perioperative oxygen fraction on surgical site infection and pulmonary complications after abdominal surgery: The PROXI randomized clinical trial.. JAMA. (2009). 302 1543–50 [Article] [PubMed]
Thibon, P, Borgey, F, Boutreux, S, Hanouz, JL, Le Coutour, X, Parienti, JJ Effect of perioperative oxygen supplementation on 30-day surgical site infection rate in abdominal, gynecologic, and breast surgery: The ISO2 randomized controlled trial.. Anesthesiology. (2012). 117 504–11 [Article] [PubMed]
Myles, PS, Leslie, K, Chan, MT, Forbes, A, Paech, MJ, Peyton, P, Silbert, BS, Pascoe, E ENIGMA Trial Group, Avoidance of nitrous oxide for patients undergoing major surgery: A randomized controlled trial.. Anesthesiology. (2007). 107 221–31 [Article] [PubMed]
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Anthony, T, Murray, BW, Sum-Ping, JT, Lenkovsky, F, Vornik, VD, Parker, BJ, McFarlin, JE, Hartless, K, Huerta, S Evaluating an evidence-based bundle for preventing surgical site infection: A randomized trial.. Arch Surg. (2011). 146 263–9 [Article] [PubMed]
Meyhoff, CS, Jorgensen, LN, Wetterslev, J, Christensen, KB, Rasmussen, LS PROXI Trial Group, Increased long-term mortality after a high perioperative inspiratory oxygen fraction during abdominal surgery: Follow-up of a randomized clinical trial.. Anesth Analg. (2012). 115 849–54 [Article] [PubMed]
Wetterslev, J, Thorlund, K, Brok, J, Gluud, C Trial sequential analysis may establish when firm evidence is reached in cumulative meta-analysis.. J Clin Epidemiol. (2008). 61 64–75 [Article] [PubMed]
Fig. 1.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1  Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1 Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
Fig. 1.
Trial sequential analysis of the nine trials included in the meta-analysis of hyperoxia to prevent surgical site infection by Hovaguimian et al.1  Solid line = cumulative Z-curve. Dashed line = trial sequential monitoring boundary. RRR = relative risk reduction.
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