Updated meta-analysis on intraoperative inspired fraction of oxygen and the risk of surgical site infection in adults undergoing general and regional anesthesia

Yoann El Maleh; Charlotte Fasquel; Christophe Quesnel; Marc Garnier

doi:10.1038/s41598-023-27588-2

. 2023 Feb 11;13:2465. doi: 10.1038/s41598-023-27588-2

Updated meta-analysis on intraoperative inspired fraction of oxygen and the risk of surgical site infection in adults undergoing general and regional anesthesia

Yoann El Maleh ¹, Charlotte Fasquel ², Christophe Quesnel ¹, Marc Garnier ^1,^✉

PMCID: PMC9922261 PMID: 36774366

Abstract

This updated meta-analysis aims at exploring whether the use of systematic high vs low intraoperative oxygen fraction (FiO₂) may decrease the incidence of postoperative surgical site infection during general (GA) or regional anesthesia (RA). PubMed, Cochrane CENTRAL, ClinicalTrials.gov databases were searched from January 1st, 1999 and July, 1st 2022, for randomized and quasi-randomized controlled trials that included patients in a high and low FiO₂ groups and reported the incidence of SSI. The meta-analysis was conducted with a DerSimonian and Laird random-effects model. Thirty studies (24 for GA and 6 for RA) totaling 18,055 patients (15,871 for GA and 2184 for RA) were included. We have low-to-moderate-quality evidence that high FiO₂ (mainly 80%) was not associated with a reduction of SSI incidence compared to low FiO₂ (mainly 30%) in all patients (RR 0.90, 95%CI 0.79–1.03). Moderate inconsistency existed between studies (I² = 38%). Subgroup analyses showed a moderate protective effect in patients undergoing GA (RR 0.86, 95%CI 0.75–0.99) (low level of evidence), while high FiO₂ was not associated with a reduction of SSI in patients undergoing RA (RR 1.17, 95%CI 0.90–1.52) (moderate level of evidence). Sensitivity analyses restricted to patients ventilated without nitrous oxide (n = 20 studies), to patients operated from abdominal surgeries (n = 21 studies), and to patients suffering from deep SSI (n = 13 studies), all showed the absence of any significant effect of high FiO₂. As a conclusion there is no compelling evidence that high FiO₂ can improve postoperative patient’s outcome on its own when good SSI prevention practices are properly applied. Recent well-designed and adequately powered randomized controlled trials add further weight to these results.

Subject terms: Bacterial infection, Risk factors

Introduction

Surgical site infections (SSI) are the most common healthcare-associated infections and a source of morbidity and over-mortality. In 2016, a systematic review and meta-analysis assessing the effects of systematic high FiO₂ (80%) compared with standard FiO₂ (30%) concluded that high FiO₂ were associated with a reduction of SSI in patients undergoing surgery under general anesthesia¹. Consequently, the WHO recommended that “adult patients undergoing general anesthesia should receive an 80% FiO₂ intra-operatively to reduce the risk of SSI”². These recommendations have sparked large debate on the benefits and harms of hyperoxemia. On the theoretical point-of-view, several pro (prevention of hypoxemia, SSI and postoperative nausea and vomiting) and con (respiratory adverse events, increased production of harmful “reactive oxygen species”) arguments have been raised by believers and detractors of high FiO₂. Accordingly, and despite these recommendations, anesthetists still used a wide range of intraoperative FiO₂ in daily practice^3,4 and frequently changed FiO₂ settings during surgery unrelated to patients’ PaO₂ or SpO₂⁵.

Then, an updated meta-analysis still reported in 2018 a beneficial effect of high FiO₂, however with an increasingly low level of evidence⁶. Consequently, the WHO downgraded the strength of its recommendations but still recommended an 80% intraoperative FiO₂ during general anesthesia⁷. In 2019, de Jonge et al. updated the meta-analysis in turn and reported a significantly lower incidence of SSI in intubated patients ventilated intra-operatively with high compared to low FiO₂ (RR 0.80 [0.64–0.99])⁸. In the same issue of the British Journal of Anesthesia, Mattishent et al. reported the results of a meta-analysis focused on the safety of high FiO₂, demonstrating the absence of significant side-effects, in particular regarding respiratory and cardiovascular events⁹. Several reasons can be suggested to explain persistent mistrust. First, de Jonge’s meta-analysis still included Myles’ ENIGMA study whereas it compared 80%O₂/20%N₂ to 30%O₂/70%N₂O and was originally designed to assess benefits and harms of nitrous oxide. Second, substantial heterogeneity remained, leading de Jonge and co-authors to conclude that “the evidence from the updated analysis has become weaker”. Third, this meta-analysis may have become obsolete very quickly, as new randomized studies were published in the following months. One year later, Hovaguimian et al. concluded in an updated meta-analysis of their former work of 2013, based on 8 studies, that the exclusion of the retracted studies by the group of Schietroma led to a “confidence interval [around the relative risk] wider, that now crossed the line of equality”¹⁰. However, despite this non-significant updated result, the authors concluded that “consistently with the WHO meta-analysis, high inspired oxygen could have a protective effect against surgical site infection”. It can be said that all this did not bring the debate to be closed.

The aim of this study was to update the meta-analysis on the potential beneficial effects of the administration of high intraoperative FiO₂ on the occurrence of SSI.

Results

Description of the included studies

The main characteristics of the studies included in the meta-analysis are summarized in Table 1 (general anesthesia) and Table 2 (regional anesthesia). Thirty-seven studies were first included (Fig. 1). Then, 3 RCT by Schietroma et al. were excluded from analysis taking into account the retraction of 2 of them due to the falsification of the statistics^11,12 and one of them for plagiarism and similarities of data with those previously published by another group¹³. The validity of the 3 non-retracted studies from this group^14–16 has also been questioned because all 6 RCT of this group reported results markedly different from the pooled results of all other published trials systematically in favor of the high FiO₂ group. Consequently, as previous authors^8–10, we followed the conclusions of the extensive re-analysis of the whole work from Schietroma’s group¹⁷ and did not include data from any study of this group in our meta-analysis.

Table 1.

Summary of the main characteristics and results of the studies including patients under general anesthesia.

Study	Country	Design, n	Type of surgery	O₂ duration in PACU	SSI definition, follow up	SSI, n (%)	Second gas	Antibiotic prophylaxis	Temp	Fluids
Greif et al.¹⁹	Austria, Germany, USA	RCT Multicenter n = 500	Colorectal	2 h	Wound infection (pus), Day 15	FiO₂ 80%: 13/250 (5.2%) FiO₂ 30%: 28/250 (11.2%) p = 0.01	N₂	NP	Yes	15 ml/kg/h
Pryor et al.²⁰	USA	RCT Monocenter n = 160	Major abdominal laparotomy or laparoscopy	2 h	Clinical and paraclinical requiring medical support, Day 14	FiO₂ 80%: 20/80 (25%) FiO₂ 35%: 9/80 (11.3%) p = 0.02	N₂O	Yes	NP	NP
Belda et al.²¹	Spain	RCT Multicenter n = 291	Colorectal laparotomy	6 h	CDC, Day 14	FiO₂ 80%: 22/148 (14.9%) FiO₂ 30%: 35/143 (24.4%) p = 0.04	Air	Yes	Yes	15 ml/kg/h
Mayzler et al.²²	Israel	RCT Monocenter n = 38	Colorectal Carcinologic	2 h	Wound infection, Day 30	FiO₂ 80%: 2/19 (12.5%) FiO₂ 30%: 3/19 (17.6%) p = 0.53	N_2, N₂O	Yes	Yes	15 ml/kg/h
Myles et al.²³	Australia	RCT Multicenter n = 2012	Major surgery > 2 h	–	Wound infection (pus or positive culture), Day 30	FiO₂ 80%: 77/997 (7.7%) FiO₂ 30%: 106/1015 (10.4%) p = 0.034	N_2, N₂O	Yes	NP	NP
Meyhoff et al.²⁴	Denmark	RCT Multicenter n = 1386	Abdominal laparotomy	2 h	CDC, Day 14	FiO₂ 80%: 131/685 (19.1%) FiO₂ 30%: 141/701 (20.1%) p = 0.64	Air	Yes (70% of cases)	Yes	Restrictive
Bickel et al.²⁵	Israel	RCT Monocenter n = 210	Appendectomy Mac Burney	2 h	ASEPSIS, Day 14	FiO₂ 80%: 6/107 (5.6%) FiO₂ 30%: 14/103 (13.6%) p = 0.04	N₂ Air	Yes	Yes	NP
Thibon et al.²⁶	France	RCT Multicenter n = 434	Abdominal laparoscopy/tomy + breast cancer surgery	–	CDC, Day 30	FiO₂ 80%: 15/226 (6.6%) FiO₂ 30%: 15/208 (7.2%) p = 0.81	Air	Yes (51.5% of cases)	NP	NP
Chen et al.²⁷	Hong Kong	RCT Monocenter n = 91	Colorectal	24 h	CDC, Day 30	FiO₂ 80% + N₂: 5/30 (16.7%) FiO₂ 30% + N₂: 4/30 (13.3%) FiO₂ 30% + N₂O: 15/31 (48.4%) p = 0.21	N₂ N₂O	Yes	Yes	NP
Stall et al.²⁸	USA	RCT Monocenter n = 235	Orthopedic trauma surgery	2 h	CDC, Day 84	FiO₂ 80%: 14/119 (12%) FiO₂ 30%: 19/116 (16%) p = 0.31	NA	Yes	NP	NP
Kurz et al.²⁹	USA, Ireland, Austria	RCT Multicenter n = 555	Colectomy laparotomy > 2 h	1 h	CDC, Day 30	FiO₂ 80%: 45/285 (15.8%) FiO₂ 30%: 42/270 (15.6%) p = 1.00	N₂	Yes	NP	6–10 ml/kg/h
Wasnik et al.³⁰	India	RCT Monocenter n = 64	Appendectomy Mac Burney	2 h	ASEPSIS, Day 14	FiO₂ 80%: 0/32 FiO₂ 30%: 0/32	NA	Yes	NP	NP
Chiang et al.³¹	New Zealand	RCT Monocenter n = 37	Vascular surgery (infra-inguinal bypass)	2 h	CDC, Day 30	FiO₂ 80%: 6/19 (incl. 0 major SSI) FiO₂ 30%: 7/18 (incl. 3 major SSI) p> 0.05	NA	Yes	Yes	NP
Kurz et al.³²	USA	Quasi-randomized Monocenter n = 5749	Major abdominal > 2 h laparotomy or laparoscopy	–	CDC, Day 30	FiO₂ 80%: 118/2896 (4.1%) FiO₂ 30%: 112/2853 (3.9%) p = 0.77	NA	Yes	Yes	NP
Mayank et al.³³	India	RCT Monocenter n = 94	Colorectal	6 h	CDC, Day 30	FiO₂ 80%: 26/47 (55.3%) FiO₂ 30%: 19/47 (40.4%) p = 0.21	N₂O	Yes	Yes	15 ml/kg/h
Alvandipour et al.³⁴	Iran	RCT Monocenter n = 80	Colorectal	1 h	ASEPSIS, 1 month following discharge	FiO₂ 80%: 2/40 (5%) FiO₂ 30%: 6/40 (15%) p< 0.05	N₂O	Yes	Yes	6–10 ml/kg/h
Ferrando et al.³⁵	Spain	RCT Multicenter n = 717	Abdominal > 2 h	3 h	CDC, Day 7 (main outcome) and day 30	FiO₂ 80%: 31/362 (8.9%) FiO₂ 30%: 34/355 (9.4%) p = 0.90 FiO₂ 80%: 52/362 (16.5%) FiO₂ 30%: 62/355 (19.9%) p = 0.89	Air	Yes (85% of cases)	NP	NP
Li et al.³⁶	China	RCT Monocenter N = 251	Abdominal > 2 h	2 h	CDC, Day 7	FiO₂ 80% 12/126 (9.5%) FiO₂ 30%: 18/125 (14.4%) RR: 1.51, p = 0.23	Air	Yes	Yes	8 ml/kg/h
Lin et al.³⁸	China	RCT Monocenter N = 630	Abdominal carcinologic 2–5 h	–	Wound infection Delay ?	FiO₂ 80% 40/316 (12.7%) FiO₂ 40%: 30/314 (9.6%) p = 0.74	Air	Yes	Yes	NP
Park et al.³⁷	Korea	RCT Monocenter N = 172	Abdominal surgery	15 min	Wound infection requiring re-intervention, During hospitalization	FiO₂ 60%: 8/87 (9%) FiO₂ 35%: 4/85 (5%) p = 0.25	Air	Yes	NP	NP
Yerra et al.³⁹	India	RCT Monocenter N = 178	Emergency abdominal surgery	2 h	CDC + microbiological culture	FiO₂ 80%: 29/85 (34.1%) FiO₂ 30%: 19/93 (20.4%)	Air	Yes	NP	NP
Reiterer et al. ⁴⁰	Austria	RCT Monocenter N = 258	Major abdominal surgery > 2 h	2 h	CDC	FiO₂ 80%: 20/128 (15.6%) FiO₂ 30%: 23/130 (17.7%) p > 0.05	NA	NA	Yes	2–3 ml/kg baseline + bolus guided by oeso. doppler
Major Extremity Trauma Research Consortium⁴¹	USA	RCT Multicenter N = 1136	Orthopedic trauma surgery	2 h	CDC, Day 182	FiO₂ 80%: 40/575 (7.0%) FiO₂ 30%: 60/561 (10.7%) RR : 0.65 [0.45–0.96]—p = 0.03	NA	Yes	NP	NP
Holse et al.⁴²	Denmark	RCT Multicenter N = 576	General surgery > 1 h	2 h	CDC Day 30	FiO₂ 80%: 32/297 (10.8%) FiO₂ 30%: 32/296 (10.8%)	NA	NA	NA	2–5 ml/kg/h

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O₂ oxygen, SSI surgical site infection, n number, Temp. temperature (i.e. protocol for maintenance of intraoperative normothermie), N₂ nitrogen, N₂O nitrous oxide, AA ambient air, CDC Centers for Disease Control and Prevention, ASEPSIS Additional treatment, Serous discharge, Erythema, Purulent discharge, Separation of deep tissues, Isolation of bacteria, and prolonged Stay in hospital > 14 days, RCT randomized controlled trial.

Table 2.

Summary of the main characteristics and results of the studies including patients under regional anesthesia.

Study	Country	Design, n	Type of surgery	O₂ duration in PACU	SSI definition, follow up	SSI, n (%)	Second gas	Antibiotic prophylaxis	Temp	Fluids
Gardella et al.⁴³	USA	RCT Monocenter n = 143	Caesarean section under regional anesthesia	2 h	Endometritis or wound infection requiring ATB, Day 14	Mask 15 L/min: FiO₂ 80%: 17/69 (25%) FiO₂ 30%: 10/74 (14%) p = 0.13	Air	Yes (at cord clamp)	NP	NP
Scifres et al.⁴⁴	USA	RCT Monocenter n = 585	Caesarean section under regional anesthesia	2 h	Endometritis or wound infection, Day 30	10 L/min (FiO₂ 80%): 35/288 (12.2%) 2 L/min (FiO₂ 30%): 26/297 (8.8%) p = 0.18	Air	Yes	NP	NP
Admadé et al.⁴⁵	Panama	RCT Monocenter n = 343	Caesarean section under regional anesthesia	2 h	Wound infection clinical signs, Day 30	FiO₂ 80%: 9/164 (5.5%) AA: 13/179 (7.3%) p = 0.33	Air	Yes	NP	NP
Duggal et al.⁴⁶	USA	RCT Monocenter n = 831	Caesarean section under regional anesthesia	1 h	CDC (SSI) + Endometritis, Day 45	10 L/min (FiO₂ 80%): 34/416 (8.2%) 10 L/min (FiO₂ 30%): 34/415 (8.2%) p = 0.89	Air	Yes	NP	NP
Williams et al.⁴⁷	USA	RCT Monocenter n = 160	Caesarean section under regional anesthesia	2 h	CDC (SSI) + endometritis, Day 42	FiO₂ 80%: 12/83 (14.5%) FiO₂ 30%: 10/77 (13.0%) p = 0.79	Air	Yes (at cord clamp)	NP	NP
Fariba et al.⁴⁸	Iran	RCT Monocenter n = 122	Caesarean section under regional anesthesia	6 h	ASEPSIS, Day 14	FiO₂ 80%: 0/61 FiO₂ 30%: 1/61 p > 0.05	Air	Yes	NP	8 ml/kg

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O₂ oxygen, SSI surgical site infection, n number, Temp. temperature (i.e. protocol for maintenance of intraoperative normothermia), N₂ nitrogen, N₂O nitrous oxide, AA ambient air, CDC Centers for Disease Control and Prevention, ASEPSIS Additional treatment, Serous discharge, Erythema, Purulent discharge, Separation of deep tissues, Isolation of bacteria, and prolonged Stay in hospital > 14 days, RCT randomized controlled trial.

In addition, the randomized study by Anthony et al.¹⁸ was excluded as they assessed a bundle of five measures including 80% FiO₂ during the surgery and the first 2 postoperative hours as compared with a standard of care using 30% FiO₂. Indeed, the specific role of high or low FiO₂ could not be individualized from other measures such as perioperative warming to maintain normothermia or reduction of intravenous fluids during the surgery in this study¹⁸. Eventually, 30 randomized studies were included in this meta-analysis for a total of 18,055 patients, among which 24 compared high vs. low intraoperative FiO₂ during general anesthesia (n = 15,871 patients)^19–42 and 6 during regional anesthesia (n = 2184 patients)^43–48. High FiO₂ was 80% in all studies except in Park’s study (FiO₂ 60%)³⁷; and low FiO₂ was 30% in all studies except in Lin’s study (FiO₂ 40%)³⁸, Pryor’s and Park’s studies (FiO₂ 35%)^20,37, Mayank’s study (FiO₂ 33%)³³, and Admadé’s study (room air)⁴⁵.

Concerning surgeries performed under general anesthesia, studies mainly included patients undergoing abdominal surgery (exclusively for 18 and mixed with other surgeries for 3 out of the 24 studies) (Table 1). Concerning surgeries performed under loco-regional anesthesia, the 6 studies included caesarean section patients treated with epidural anesthesia (Table 2). SSI was the main judgment criterion in 22 studies^{19–22,24–26,28–30,32–35,39,41,43–48}, and a secondary endpoint in the 8 remaining studies^{23,27,31,36–38,40,42}.

SSI were diagnosed using the CDC definition^{21,24,26–29,31–33,35,36,39,41,42,46,47}, ASEPSIS definition^25,30,34,48, or other trial-specific definitions^{19,20,22,23,37,38,40,43–45}, in respectively 16, 4 and 10 out of the 30 included studies. Confounding factors influencing the incidence of SSI were variously considered. Antibiotic prophylaxis was protocolized in all studies but sometimes incompletely followed. Maintenance of perioperative normothermia was protocolized in only 13/30 studies^{19,21–25,27,31–34,36,38}. Amount of perioperative fluid administered and fluid management strategy was protocolized in 9/30 studies^{19,21,22,24,29,33,34,40,42}.

Meta-analysis and sub-group analyses depending on anesthetic modalities

The Oxford quality-scoring system of the 30 studies included in the meta-analysis is summarized in Fig. 2.

Risk of bias summary for the 30 studies included in the meta-analysis. Green circles represent low risk of bias, yellow circles represent unclear of moderate risk of bias, and red circles represent high risk of bias.

Meta-analysis of the 30 studies showed no significant benefit of high FiO₂ on the prevention of SSI (RR0.90, 95%CI 0.79 to 1.03) (Fig. 3a). There was evidence of heterogeneity (τ² = 0.04, χ² test for heterogeneity p = 0.02, I² = 38%). Visual inspection of the funnel-plot showed no clear evidence of publication bias, as confirmed by Egger’s test (Z = − 0.774, p = 0.44) and the rank correlation test (Kendall’s τ = − 0.103, p = 0.44) (Fig. 3b).

Forest plot analysis of high *vs.* low intraoperative FiO₂ on the incidence of SSI (a), within the subgroups of patients operated under general anesthesia and loco-regional anesthesia; and corresponding funnel plots (b). The X-axis of forest plots represents relative risk, and each row on the Y-axis represents an individual study. The blue squares and horizontal lines represent point estimates and corresponding 95% confidence intervals of the individual studies. The black diamonds represent the overall analysis.

Considering sub-group analyses depending on anesthetic modalities, a moderate benefit was found in patients operated under general anesthesia (RR 0.86, 95%CI 0.75–0.99) (Fig. 3a). There was evidence of heterogeneity (τ² = 0.04, χ² test for heterogeneity p = 0.02, I² = 41%). Visual inspection of the funnel-plot showed no clear evidence of publication bias, as confirmed by Egger’s test (Z = − 0.822, p = 0.41) and the rank correlation test (Kendall’s τ = − 0.109, p = 0.48) (Fig. 3b). According to the GRADE methodology, the overall quality of evidence for prevention of surgical site infection was assessed as low due to biases in individual trials and inconsistency between studies (I² = 41%).

Meta-analysis of the 6 studies that included patients operated on under regional anesthesia showed no significant benefit of high FiO₂ on the prevention of SSI (RR 1.17, 95%CI 0.90–1.52—Fig. 3a), with good between-study homogeneity (τ² = 0.00, χ² test for heterogeneity p = 0.53, I² = 0%). Visual inspection of the funnel-plot showed no clear evidence of publication bias, as confirmed by Egger’s test (Z = − 0.561, p = 0.58) and the rank correlation test (Kendall’s τ = − 0.067, p = 1.00) (Fig. 3b). According to GRADE methodology, the overall certainty for prevention of surgical site infection was assessed as moderate, taking into account the absence of inconsistency (I² = 0%) but biases in individual studies and the imprecision of the 95%CI around the estimate.

Sensitivity analyses

Second gases

Considering that it has been suggested that nitrous oxide could impair human immune functions, sensitivity analyses were conducted: (1) on the 22 studies that used the same second gas in both the high and low FiO₂ groups, i.e. excluding the 2 studies that compared “low FiO₂ + nitrous oxide” to “high FiO₂ + nitrogen”^22,23, and the “low FiO₂ + nitrous oxide” group of Chen’s study²⁷“; showing no significant effect of high intraoperative FiO₂ (RR 0.89, 95%CI 0.76–1.03—Fig. 4a); and (2) on the 20 studies that did not use nitrous oxide as second gas, neither in the high nor low FiO₂ groups; showing no significant effect of high intraoperative FiO₂ (RR 0.87, 95%CI 0.75–1.01—Fig. 4b).

Sensitivity analysis of high versus low intraoperative FiO₂ on the incidence of SSI in patients operated under general anesthesia restricted to the 22 studies that used the same second gas in both the high and low FiO₂ group (a); and to the 20 studies that did not use nitrous oxide as second gas, neither in the high nor low FiO₂ groups (b).

Types of surgery

Considering that the type of surgery is an important factor associated with the occurrence of SSI, a sensitivity analysis was conducted on the 18 studies having exclusively included patients operated from abdominal surgeries^{19–22,24,25,27,29,30,32–40} and on the subgroup of patients from the 3 studies having included mixed surgeries who were operated from abdominal surgeries, after having obtained additional data regarding these subgroups from the authors^23,26,42. No significant benefit of high FiO₂ on the prevention of SSI in abdominal surgery was found (RR0.89, 95%CI 0.76–1.04) (Fig. 5).

Sensitivity analysis of high *vs.* low intraoperative FiO₂ on the incidence of SSI in patients operated from abdominal surgery, included in the 18 studies having exclusively included patients operated from abdominal surgeries and in the 3 studies having included mixed surgeries.

Types of SSI

Considering that superficial SSI, sometimes only treated by local measures of the wound, may be not associated to the same morbidity and mortality than deep SSI, a sensitivity analysis was conducted on the 15 studies for which data on superficial and deep SSI were available or retrieved from the authors. No significant benefit of high FiO₂ on the prevention of deep SSI was found (RR0.97, 95%CI 0.83–1.14) (Fig. 6).

Sensitivity analysis of high versus low intraoperative FiO₂ on the incidence of deep SSI in patients included in the 15 studies for which data regarding superficial and deep SSI were available or retrieved from the authors.

Discussion

This updated meta-analysis performed on 30 RCT published between 2000 and July 2022 showed no significant benefit of a high FiO₂ on the prevention of SSI when considering all types of surgery and anesthetic modalities. This result is even more robust in patients having caesarean section under epidural or spinal anesthesia, leading to recommend that routine administration of supplemental oxygen to these patients should be avoided, considering the absence of any impact on neither maternal nor fetal prognosis⁴⁹. Focusing on patients operated under general anesthesia, a moderate reduction of the incidence of SSI in the high intraoperative FiO₂ group was observed (RR 0.86, 95%CI 0.75–0.99), however somewhat smaller than that reported by de Jonge et al. on studies from 1990 to 2018 (RR 0.80 [0.64–0.99])⁸. The inclusion of the large ENIGMA study in the analysis, whose sample represented more than one third of the total population included in de Jonge’s meta-analysis, may be a source of discussion. Indeed, ENIGMA study, like Mayzler’s study²², used nitrous oxide as second gas in the low FiO₂ group and nitrogen in the high FiO₂ group, while it has been suggested that nitrous oxide could impair human immune functions and favor SSI^50–52. However, current evidence does not support any relevant clinical effect of nitrous oxide on SSI occurrence⁵³. Consequently, despite an experimental plan not designed originally to assess the role of high vs. low FiO₂ but rather benefits and harms of nitrous oxide, we chose, as previously done by de Jonge et al. to include Myles’ and Mayzler’s studies in the meta-analysis. One of the advantages of our meta-analysis other the latter is the inclusion of ten new randomized studies published since then^33–42, representing 4019 additional patients. In addition, we believe de Jonge et al. missed the studies by Chiang et al. (for patients under general anesthesia)³¹ and Admadé et al. (for patients under general anesthesia)⁴⁵, yet published within their inclusion period in 2017 and 2013 respectively. Finally, we believe that Kurz’s controlled cluster trial should have been included as this design comprised protections against biases very close to studies randomized at patient’s level, and provided data based on by far the largest sample of patients. To summarize, our analysis was performed on 30 controlled trials totaling 18,055 patients, compared to 17 studies and 7817 patients in de Jonge’s meta-analysis.

For all that, does this result allow us to conclude definitively that a high intraoperative FiO₂ is useful to prevent SSI in intubated patients? We believe that not at all. First, our meta-analysis, as did the previous ones, presents substantial heterogeneity making difficult to take the results at face value. Indeed, some studies included very small samples of less than 100 patients^{22,27,30,31,33,34} while others included more than 500 patients^{23,24,29,32,35,38,41,42,44,46}. The incidence of SSI was also very different among studies, from a few percent in some studies^26,30,32,42 to 20% or more in others^{21,24,31,33,39}. Differences in the incidence of SSI among studies may also be explained by the heterogeneous control of the confounding risk factors of SSI, such as correct administration of antibiotic prophylaxis, perioperative maintenance of normothermia, amount of fluids infused during the perioperative period, etc. In addition, definitions and times of assessment of SSI may have differed between studies, by using CDC or ASEPSIS definitions or other “home-made” diagnostic criteria; or considering only deep of both superficial and deep SSI. Finally, the surgical site (abdominal vs. extra-abdominal), the surgical approach (laparotomy or laparoscopy), and the indication of surgery (acute vs. planned surgery, carcinologic vs. non-carcinologic surgery) were heterogeneous among studies, while these parameters are known to impact SSI incidence.

Second, beyond the heterogeneity itself, the level of evidence of our meta-analysis, like others on the field, is only low to moderate depending on the considered sub-groups. For patients under general anesthesia, the numerous biases of individual studies (Fig. 1) and the imprecision of the 95%CI around the estimate despite more than 20 studies included in the meta-analysis, led to downgrade the level of evidence. As an example, adding only 5 SSI in the “high FiO₂ group”, out of a total of more than 680 SSI, makes the confidence interval crossing the identity line, leading to conclude to the absence of significant effect. This highlights the fragility of the conclusions that could be drawn from this unrestricted analysis.

In this context, sensitivity analyses restricted to more homogenous populations may be more informative. Along these lines, no significant effect of a high intraoperative FiO₂ was found for patients operated from abdominal surgeries under general anesthesia; no more than for patients anesthetized without nitrous oxide; or even for the prevention of deep SSI rather than all types of SSI. We believe that this absence of protective effect in these subgroups of interest strongly reduces the potential interest of systematic high intraoperative FiO₂. This becomes even more relevant when considering the results of another recent meta-analysis focusing on the effect of high vs. low intraoperative FiO₂ on respiratory outcomes, which did not report any beneficial effect on clinical outcomes such as hospital length-of-stay or mortality, and on the contrary a higher incidence of postoperative radiographic atelectasis associated with reduced postoperative PaO₂ values⁵⁴.

Finally, our results and others also demonstrate that meta-analyses are not magic tools able to overcome limits or biases presented by individual studies. In this context, considering the results of well-designed, multicenter, adequately powered randomized controlled trials, using the latest ventilatory and SSI prevention standards should be a more relevant approach than swearing by meta-analyses. In that case, the most recent randomized studies reported no difference on the incidence of SSI with high or low FiO₂ in patients undergoing general anesthesia. The PROXI study, the largest multicenter randomized controlled trial specifically designed to assess the role of high vs. low intraoperative FiO₂ on SSI³⁹, did not report any reduction of the incidence of SSI with the administration of 80% FiO₂ during colorectal surgery. Similarly, the recent multicenter randomized iPROVE-O₂ trial that included 740 patients undergoing major abdominal surgery, ventilated intraoperatively with an evidence-based protective strategy, reported a similar SSI rate between the 30% and 80% FiO₂ groups³⁵. Indeed, 80% FiO₂ did not reduce postoperative SSI (8.9% vs 9.4%, RR 0.94 95%CI (0.59–1.50)—p = 0.90), as none of the secondary outcomes including hospital length-of-stay or short-term mortality. We believe that these results from individual high-quality RCT add further weight and reinforce the conclusion that there is no compelling evidence that high FiO₂ can improve postoperative patient’s outcome on its own when good SSI prevention practices are properly applied. Consequently, we believe that abrogation of the WHO recommendation on the systematic use of high intraoperative FiO₂ must be seriously discussed.

Methods

This meta-analysis followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines. The PRISMA checklist is available as a Supplementary file.

Registration

A standard protocol was developed and registered prior to literature search on the PROSPERO database on June 1st 2021 (registration number CRD42021258279). The protocol is available as a Supplementary file.

Search strategy

A search was conducted for studies published between January 1st, 1999 and July, 1st 2022 in MEDLINE (PubMed), CENTRAL (Cochrane), EMBASE (Elsevier) and ClinicalTrials.gov databases. The last search was conducted on July, 5th 2022. The research question was formulated according to the PICO format: in adult patients undergoing general or loco-regional anesthesia (P), does a systematic high intra-operative FiO₂ (> 50%) (I) lead to reduced incidence of surgical site infection (O) compared to low FiO₂ (≤ 50%) (C)? Then, the following search equation was designed: ((“Perioperative" [All Fields] OR "intraoperative" [All Fields]) AND ("FiO₂" [All Fields] OR "inspired oxygen fraction" [All Fields] OR "oxygen concentration" [All Fields]) OR ("anaesthesia" [All Fields] OR "anesthesia" [MeSH Terms] OR "anesthesia" [All Fields] OR "anaesthesias" [All Fields] OR "anesthesias" [All Fields] OR "general anesthesia" [All Fields] OR "general anaesthesia" [All Fields])) AND ("surgical wound infection" [MeSH Terms] OR ("surgical" [All Fields] AND "wound" [All Fields] AND "infection" [All Fields]) OR "surgical wound infection" [All Fields] OR ("surgical" [All Fields] AND "site" [All Fields] AND "infection" [All Fields]) OR "surgical site infection" [All Fields]) OR ("outcomes" [All Fields] OR "adverse effects" [All Fields] OR "adverse events" [All Fields] OR "death" [All Fields]) AND ("pulmonary complications" [All Fields] OR "atelectasis" [All Fields]). Only randomized studies (including quasi-randomized studies and cluster-randomized studies in which the intervention was not randomized at the patient level but by day, week or specific operating theatre) were included in this meta-analysis. In addition, the references of the selected articles were also screened to complete the search. Finally, the PubMed “similar article” and “citing article” functions were used to expand the search.

Study selection

Two authors (Y.E. and M.G.) independently screened the titles and abstracts retrieved from the systematic search for potential eligibility. In case of discrepancy, the eligibility was discussed with a third author (C.F). To be considered for analysis, publications had to be written in English or in French. When the title and abstract indicated potential eligibility, the full-text article was analysed. The PRISMA flow diagram of study selection is presented in Fig. 1.

Data extraction and analysis

For each study, a first reviewer extracted the following data: first author, year of publication, study location, type of study, population studied, type of surgery, primary and secondary outcomes selected, and main results. Potential confounding factors that may influence the selected outcomes (for example the perioperative use of antibiotics, the composition of the inspired gas mixture, the use of a protocol to avoid perioperative hypothermia, etc.) were reported. A second reviewer checked independently the extracted data. In case of discrepancy, the data were discussed with a third reviewer and a consensus decision was made. Study sample size and the relevance of the research were considered at the level of each study. Then, the methodological quality of studies was rated with the Oxford quality scoring system considering the SSI outcome¹⁹.

Meta-analysis

A quantitative review of the extracted data was made for the judgment criterion (i.e. incidence of SSI). This primary outcome was expressed using the pooled relative risk with its 95% confidence interval (RR 95%CI). A DerSimonian and Laird random-effects model of meta-analysis was used to account for potential clinical and statistical heterogeneity. The χ² test for heterogeneity was computed and the amount of heterogeneity was quantified by the I² statistic. The extent of heterogeneity was evaluated using the between-study variance (τ²). Sensitivity analyses including only (1) studies using the same second gas in both the high and low FiO₂ groups, and (2) studies using nitrogen or room air as second gas in both the high and low FiO₂ groups (i.e. not including studies that used nitrous oxide as second gas) were planned. Then, sensitivity analyses regarding the type of surgery (abdominal vs. non abdominal), and the type of SSI (deep vs. superficial) were also performed. According to the CDC definition, SSI were considered as “deep SSI” is they were classified as “deep” or “organ/space”.

Eventually, publication bias was evaluated by a visual inspection of funnel plots and assessed with Egger’s regression test and the rank correlation test for funnel plot asymmetry. Statistical analyses were performed using Review Manager (RevMan) 5.4.1 (Cochrane Collaboration, The Nordic Cochrane Centre, Copenhagen, Denmark) and Jamovi 2.0 (The Jamovi Project).

Quality of evidence

The certainty of the overall evidence for the potential association between the use of high vs. low FiO₂ and SSI incidence was evaluated using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) methodology, and reported as “very low”, “low”, “moderate” or “high” taking into account study limitations, inconsistency of evidence, indirectness of evidence and reporting bias⁵⁵.

Supplementary Information

Supplementary Information 1.^{(37.4KB, docx)}

Supplementary Information 2.^{(1.8MB, pdf)}

Acknowledgements

We would like to thank Pr Olivier Huet from the Anesthesiology and Critical Care Medicine Department of Brest University Hospital for his assistance with the study.

Author contributions

Y.E.M.: conceptualization, investigation, writing—original draft. C.F.: conceptualization, investigation, writing—review and editing. C.Q.: conceptualization, supervision, writing—review and editing. M.G.: conceptualization, investigation, supervision, methodology, formal analysis, writing—original draft, writing—review and editing.

Data availability

All data generated or analyzed during this study are included in this published article and its supplementary information files.

Competing interests

The authors declare no competing interests.

Footnotes

Publisher's note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Supplementary Information

The online version contains supplementary material available at 10.1038/s41598-023-27588-2.

References

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary Information 1.^{(37.4KB, docx)}

Supplementary Information 2.^{(1.8MB, pdf)}

Data Availability Statement

All data generated or analyzed during this study are included in this published article and its supplementary information files.

[CR1] 1.WHO. Web appendix 13a: summary of the systematic review on perioperative oxygenation. Global guidelines for the prevention of surgical site infection (2016).

[CR2] 2.WHO. Global guidelines for the prevention of surgical site infection—2016 (2016). [PubMed]

[CR3] 3.LAS Vegas investigators Epidemiology, practice of ventilation and outcome for patients at increased risk of postoperative pulmonary complications: LAS VEGAS - an observational study in 29 countries. Eur. J. Anaesthesiol. 2017;34:492–507. doi: 10.1097/EJA.0000000000000646. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CR4] 4.Morkane CM, McKenna H, Cumpstey AF, Oldman AH, Grocott MPW, Martin DS, et al. Intraoperative oxygenation in adult patients undergoing surgery (iOPS): A retrospective observational study across 29 UK hospitals. Perioper. Med. Lond. Engl. 2018;7:17. doi: 10.1186/s13741-018-0098-3. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CR5] 5.Karalapillai D, Weinberg L, Peyton PJ, Ellard L, Hu R, Pearce B, et al. Frequency of hyperoxaemia during and after major surgery. Anaesth. Intensive Care. 2020;48:213–220. doi: 10.1177/0310057X20905320. [DOI] [PubMed] [Google Scholar]

[CR6] 6.Cohen B, Schacham YN, Ruetzler K, Ahuja S, Yang D, Mascha EJ, et al. Effect of intraoperative hyperoxia on the incidence of surgical site infections: A meta-analysis. Br. J. Anaesth. 2018;120:1176–1186. doi: 10.1016/j.bja.2018.02.027. [DOI] [PubMed] [Google Scholar]

[CR7] 7.WHO. Global Guidelines for the Prevention of Surgical Site Infection—2018 (2018). [PubMed]

[CR8] 8.de Jonge S, Egger M, Latif A, Loke YK, Berenholtz S, Boermeester M, et al. Effectiveness of 80% vs 30–35% fraction of inspired oxygen in patients undergoing surgery: An updated systematic review and meta-analysis. Br. J. Anaesth. 2019;122:325–334. doi: 10.1016/j.bja.2018.11.024. [DOI] [PubMed] [Google Scholar]

[CR9] 9.Mattishent K, Thavarajah M, Sinha A, Peel A, Egger M, Solomkin J, et al. Safety of 80% vs 30–35% fraction of inspired oxygen in patients undergoing surgery: A systematic review and meta-analysis. Br. J. Anaesth. 2019;122:311–324. doi: 10.1016/j.bja.2018.11.026. [DOI] [PubMed] [Google Scholar]

[CR10] 10.Hovaguimian F, Elia N, Tramèr MR. Supplemental oxygen and the risk of surgical site infection: Evidence of compromised data requires correction of previously published meta-analysis. Anesthesiology. 2019;131:932–933. doi: 10.1097/ALN.0000000000002897. [DOI] [PubMed] [Google Scholar]

[CR11] 11.Schietroma M, Cecilia EM, Sista F, Carlei F, Pessia B, Amicucci G. High-concentration supplemental perioperative oxygen and surgical site infection following elective colorectal surgery for rectal cancer: A prospective, randomized, double-blind, controlled, single-site trial. Am. J. Surg. 2014;208:719–726. doi: 10.1016/j.amjsurg.2014.04.002. [DOI] [PubMed] [Google Scholar]

[CR12] 12.Schietroma M, Piccione F, Cecilia EM, Carlei F, De Santis G, Sista F, et al. RETRACTED: How does high-concentration supplemental perioperative oxygen influence surgical outcomes after thyroid surgery? A prospective, randomized, double-blind, controlled, monocentric trial. J. Am. Coll. Surg. 2015;220:921–933. doi: 10.1016/j.jamcollsurg.2015.01.046. [DOI] [PubMed] [Google Scholar]

[CR13] 13.Schietroma M, Carlei F, Cecilia EM, Piccione F, Bianchi Z, Amicucci G. Colorectal Infraperitoneal anastomosis: The effects of perioperative supplemental oxygen administration on the anastomotic dehiscence. J. Gastrointest. Surg. Off. J. Soc. Surg. Aliment. Tract. 2012;16:427–434. doi: 10.1007/s11605-011-1717-1. [DOI] [PubMed] [Google Scholar]

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PERMALINK

Updated meta-analysis on intraoperative inspired fraction of oxygen and the risk of surgical site infection in adults undergoing general and regional anesthesia

Yoann El Maleh

Charlotte Fasquel

Christophe Quesnel

Marc Garnier

Abstract

Introduction

Results

Description of the included studies

Table 1.

Table 2.

Figure 1.

Meta-analysis and sub-group analyses depending on anesthetic modalities

Figure 2.

Figure 3.

Sensitivity analyses

Second gases

Figure 4.

Types of surgery

Figure 5.

Types of SSI

Figure 6.

Discussion

Methods

Registration

Search strategy

Study selection

Data extraction and analysis

Meta-analysis

Quality of evidence

Supplementary Information

Acknowledgements

Author contributions

Data availability

Competing interests

Footnotes

Supplementary Information

References

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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