Efficacy and safety of sugammadex versus neostigmine in reversing neuromuscular blockade in adults

Abstract

Background: Acetylcholinesterase inhibitors, such as neostigmine, have traditionally been used for reversal of non-depolarizing neuromuscular blocking agents. However, these drugs have significant limitations, such as indirect mechanisms of reversal, limited and unpredictable efficacy, and undesirable autonomic responses. Sugammadex is a selective relaxant-binding agent specifically developed for rapid reversal of non-depolarizing neuromuscular blockade induced by rocuronium. Its potential clinical benefits include fast and predictable reversal of any degree of block, increased patient safety, reduced incidence of residual block on recovery, and more efficient use of healthcare resources.

Objectives: The main objective of this review was to compare the efficacy and safety of sugammadex versus neostigmine in reversing neuromuscular blockade caused by non-depolarizing neuromuscular agents in adults.

Search methods: We searched the following databases on 2 May 2016: Cochrane Central Register of Controlled Trials (CENTRAL); MEDLINE (WebSPIRS Ovid SP), Embase (WebSPIRS Ovid SP), and the clinical trials registries www.controlled-trials.com, clinicaltrials.gov, and www.centerwatch.com. We re-ran the search on 10 May 2017.

Selection criteria: We included randomized controlled trials (RCTs) irrespective of publication status, date of publication, blinding status, outcomes published, or language. We included adults, classified as American Society of Anesthesiologists (ASA) I to IV, who received non-depolarizing neuromuscular blocking agents for an elective in-patient or day-case surgical procedure. We included all trials comparing sugammadex versus neostigmine that reported recovery times or adverse events. We included any dose of sugammadex and neostigmine and any time point of study drug administration.

Data collection and analysis: Two review authors independently screened titles and abstracts to identify trials for eligibility, examined articles for eligibility, abstracted data, assessed the articles, and excluded obviously irrelevant reports. We resolved disagreements by discussion between review authors and further disagreements through consultation with the last review author. We assessed risk of bias in 10 methodological domains using the Cochrane risk of bias tool and examined risk of random error through trial sequential analysis. We used the principles of the GRADE approach to prepare an overall assessment of the quality of evidence. For our primary outcomes (recovery times to train-of-four ratio (TOFR) > 0.9), we presented data as mean differences (MDs) with 95 % confidence intervals (CIs), and for our secondary outcomes (risk of adverse events and risk of serious adverse events), we calculated risk ratios (RRs) with CIs.

Main results: We included 41 studies (4206 participants) in this updated review, 38 of which were new studies. Twelve trials were eligible for meta-analysis of primary outcomes (n = 949), 28 trials were eligible for meta-analysis of secondary outcomes (n = 2298), and 10 trials (n = 1647) were ineligible for meta-analysis.We compared sugammadex 2 mg/kg and neostigmine 0.05 mg/kg for reversal of rocuronium-induced moderate neuromuscular blockade (NMB). Sugammadex 2 mg/kg was 10.22 minutes (6.6 times) faster then neostigmine 0.05 mg/kg (1.96 vs 12.87 minutes) in reversing NMB from the second twitch (T2) to TOFR > 0.9 (MD 10.22 minutes, 95% CI 8.48 to 11.96; I2 = 84%; 10 studies, n = 835; GRADE: moderate quality).We compared sugammadex 4 mg/kg and neostigmine 0.07 mg/kg for reversal of rocuronium-induced deep NMB. Sugammadex 4 mg/kg was 45.78 minutes (16.8 times) faster then neostigmine 0.07 mg/kg (2.9 vs 48.8 minutes) in reversing NMB from post-tetanic count (PTC) 1 to 5 to TOFR > 0.9 (MD 45.78 minutes, 95% CI 39.41 to 52.15; I2 = 0%; two studies, n = 114; GRADE: low quality).For our secondary outcomes, we compared sugammadex, any dose, and neostigmine, any dose, looking at risk of adverse and serious adverse events. We found significantly fewer composite adverse events in the sugammadex group compared with the neostigmine group (RR 0.60, 95% CI 0.49 to 0.74; I2 = 40%; 28 studies, n = 2298; GRADE: moderate quality). Risk of adverse events was 28% in the neostigmine group and 16% in the sugammadex group, resulting in a number needed to treat for an additional beneficial outcome (NNTB) of 8. When looking at specific adverse events, we noted significantly less risk of bradycardia (RR 0.16, 95% CI 0.07 to 0.34; I2= 0%; 11 studies, n = 1218; NNTB 14; GRADE: moderate quality), postoperative nausea and vomiting (PONV) (RR 0.52, 95% CI 0.28 to 0.97; I2 = 0%; six studies, n = 389; NNTB 16; GRADE: low quality) and overall signs of postoperative residual paralysis (RR 0.40, 95% CI 0.28 to 0.57; I2 = 0%; 15 studies, n = 1474; NNTB 13; GRADE: moderate quality) in the sugammadex group when compared with the neostigmine group. Finally, we found no significant differences between sugammadex and neostigmine regarding risk of serious adverse events (RR 0.54, 95% CI 0.13 to 2.25; I2= 0%; 10 studies, n = 959; GRADE: low quality).Application of trial sequential analysis (TSA) indicates superiority of sugammadex for outcomes such as recovery time from T2 to TOFR > 0.9, adverse events, and overall signs of postoperative residual paralysis.

Authors' conclusions: Review results suggest that in comparison with neostigmine, sugammadex can more rapidly reverse rocuronium-induced neuromuscular block regardless of the depth of the block. Sugammadex 2 mg/kg is 10.22 minutes (˜ 6.6 times) faster in reversing moderate neuromuscular blockade (T2) than neostigmine 0.05 mg/kg (GRADE: moderate quality), and sugammadex 4 mg/kg is 45.78 minutes (˜ 16.8 times) faster in reversing deep neuromuscular blockade (PTC 1 to 5) than neostigmine 0.07 mg/kg (GRADE: low quality). With an NNTB of 8 to avoid an adverse event, sugammadex appears to have a better safety profile than neostigmine. Patients receiving sugammadex had 40% fewer adverse events compared with those given neostigmine. Specifically, risks of bradycardia (RR 0.16, NNTB 14; GRADE: moderate quality), PONV (RR 0.52, NNTB 16; GRADE: low quality), and overall signs of postoperative residual paralysis (RR 0.40, NNTB 13; GRADE: moderate quality) were reduced. Both sugammadex and neostigmine were associated with serious adverse events in less than 1% of patients, and data showed no differences in risk of serious adverse events between groups (RR 0.54; GRADE: low quality).

Conflict of interest statement

Ana‐Marija Hristovska declares no conflict of interest.

Patricia Duch declares no conflict of interest.

Mikkel Allingstrup declares no conflict of interest.

Arash Afshari declares no conflict of interest.

Figures

1

TSA of all trials comparing sugammadex 2.0 mg/kg vs neostigmine 0.05 mg/kg; recovery time from T2 to TOFR > 0.9 minutes. With a required information size of 106, firm evidence in place favours sugammadex in a random‐effects model, with an alfa‐boundary adjusted MD of ‐10.22 (95% CI ‐12.11 to ‐8.33; diversity (D2) = 87%, I2 = 84%, random‐effects model). The cumulative Z‐curve crosses the monitoring boundary constructed for the required information size with 80% power and alpha of 0.05. However, none of the included trials had low risk of bias, and because TSA is ideally designed for trials with low risk of bias and cannot be adjusted for risk of bias, the precision of our findings has to be downgraded. Furthermore, the degree of diversity and heterogeneity is high, which once again raises questions about the reliability of the calculated required information size.

2

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

3

TSA of dichotomous data on drug‐related risk of adverse events; sugammadex (any dose) vs neostigmine (any dose). This analyses includes continuity adjustment for zero event trials (0.001 in each arm) resulting in an alfa‐boundary adjusted RR of 0.62 (95% CI 0.51 to 0.74; diversity (D2) = 34%, I2 = 14%, random‐effects model), with a control event proportion of 27.97%. With the required information size of 502, analyses indicated firm evidence favouring sugammadex with 2298 participants included corresponding to a relative risk reduction (RRR) of 38% with 80% power and alpha of 0.05. Despite the fact that the cumulative Z‐curve does not cross the monitoring boundary directly, it is hard to imagine future trials radically changing the overall picture of this analysis. However, none of the included trials were at low risk of bias, and this does downgrade the reliability of our finding.

4

TSA of dichotomous data on risk of signs of residual neuromuscular blockade; sugammadex (any dose) vs neostigmine (any dose). With continuity adjustment for zero event trials (0.001 in each arm), TSA resulted in an alfa‐boundary adjusted RR of 0.4 (95% CI 0.27 to 0.59; diversity (D2) = 0%, I2 = 0%, random‐effects model, with 80% power and alpha of 0.05), with a control event proportion of 13.08%. Cumulative Z‐curve crosses the monitoring boundary constructed for a required information size of 424 participants, indicating firm evidence in favour of sugammadex. However, none of the included trials had low risk of bias, and this equally diminishes the reliability and precision of our estimates.

5

Study flow diagram.

6

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.