Neuromuscular Blocking Agents for ARDS: A Systematic Review and Meta-Analysis

Discussion

In this meta-analysis, we found that 48 h of NMBA therapy in subjects with early, moderate-to-severe ARDS is associated with a decrease in 21–28-d mortality but has no effect on 90-d mortality. NMBAs also reduce the incidence of VILI and do not increase the risk of ICU-acquired weakness. Short-term use of NMBAs in subjects with early ARDS improves oxygenation but does not decrease duration of mechanical ventilation. The results of our meta-analysis are similar to previous meta-analyses that included 3 and 5 studies, respectively,^21,22 but in light of the ROSE¹³ results, our findings differ with regard to 90-d mortality.

The results of our meta-analysis include the results of the ROSE trial, the largest trial to date, which reported no mortality benefit associated with NMBA use at 90 d regardless of ARDS severity or duration.¹³ These results differ from the ACURASYS trial, which reported a 90-d mortality benefit associated with NMBA use.¹⁰ ROSE and ACURASYS account for 86% of the subjects assessed in this meta-analysis, and both are methodologically sound and associated with a low risk of bias and moderate quality of evidence.^10,13 Our meta-analysis noted that NMBAs improved 21–28-d mortality, but there was moderate heterogeneity (I² = 60%) among trials included in this analysis. Most likely, differences in methodology, particularly mechanical ventilation strategies such as incorporation of high PEEP, led to outcome variations among trials.^8–11,13

Despite the strengths of the ACURASYS and ROSE trials, there are a few key differences between these trials that may have resulted in conflicting outcomes. First, in ACURASYS, both the control arm and the NMBA arm received deep sedation.¹⁰ In ROSE, subjects who were randomized to NMBAs received deep sedation, but for subjects in the control arm, light sedation was targeted and daily sedation interruptions were encouraged.¹³ Recent studies have shown that deeper levels of sedation in the early phases of ARDS can increase the likelihood of reverse triggering, a form of ventilator asynchrony that can result in breath-stacking, VILI, and increased mortality.^23–25 Although both trials protocolized ventilator management and utilized lung-protective ventilation, the ROSE trial also used a high-PEEP strategy,^10,13 which has been associated with improved recruitment and decreased lung stress and atelectrauma.² There was no difference in PEEP when comparing control and NMBA subjects on days 0–7 of both the ACURASYS and ROSE trials,^10,13 suggesting the impact of NMBAs may be minimized when added to a high-PEEP strategy like that utilized in the ROSE trial. Another key difference was the time to enrollment between the ACURASYS and ROSE trials. The mean time to inclusion for subjects in ACURASYS was 21–22 h, whereas the median time to randomization for subjects enrolled in ROSE was 6.8–8.2 h.^10,13 As previously reported,²⁶ a subset of subjects with moderate-to-severe ARDS improve within 24 h of intubation, and just by virtue of the timing of enrollment, these subjects would be excluded from ACURASYS and would be randomized in ROSE. Despite the methodological differences between these 2 studies, the results of this meta-analysis highlight the importance of nonpharmacologic treatment. These approaches include utilizing PEEP optimization, lung-protective ventilation, and the addition of NMBAs in patients who require additional control of unrestrained and potentially dangerous patterns of spontaneous breathing, thereby reducing discomfort and demands for oxygen delivery and ventilation.

In our meta-analysis, use of NMBAs was associated with an improvement in the ratio at 48 h and 72 h after NMBA initiation. Plateau pressures did not improve with the use of NMBAs, and there was no significant difference in the utilization of PEEP with NMBA use. Additionally, improvements in oxygenation did not translate to decreased duration of mechanical ventilation or an increase in ventilator-free days. Subjects who received NMBAs had significantly less VILI, including barotrauma and pneumothorax. Currently, lung-protective ventilator strategies are recommended as the first-line of management to reduce the incidence of VILI in patients with ARDS by minimizing inflation pressures and providing recruitment.^2,3,27 In the included studies in this meta-analysis, both the NMBA and control arms followed the same mechanical ventilation protocols, and subjects had similar tidal volumes and PEEP at baseline. Given that factors thought to be related to reduced incidence of VILI in patients with ARDS were similar at baseline in both the subjects who received NMBAs and those who received usual care, the anti-inflammatory properties of NMBAs may be the reason for decreased VILI.^9,27

The use of NMBAs is not without risk. NMBA use has been associated with ICU-acquired weakness. A meta-analysis evaluating the use of NMBAs and associated neuromuscular dysfunction in critically ill subjects found an association (odds ratio 1.25, 95% CI 1.06–1.48, I² = 16%), but no association was noted when evaluating only studies with a low risk of bias (odds ratio 1.21, 95% CI 0.67–2.19).²⁸ Similar to a prior meta-analysis,²¹ we found no increased incidence of ICU-acquired weakness in subjects with ARDS who received a short course of NMBA therapy. A recent study evaluating NMBA use in mechanically ventilated subjects with sepsis reported that NMBAs provided the greatest mortality benefit if they were used for < 2 d.²⁹ These findings, in addition to studies evaluating NMBAs in subjects with ARDS, suggests that short NMBA courses are superior for both efficacy and safety outcomes.

Our systematic review and meta-analysis has a few limitations. First, we did not contact authors of studies for additional data, and this meta-analysis was not completed using individual subject data. Additionally, we did not contact authors of studies that evaluated NMBAs for ARDS but did not report 21–28-d and 90-d mortality. Unfortunately, none of the reported outcomes in this meta-analysis were evaluated by all 6 included studies. This may have resulted in a loss of analyzable data, although we find it unlikely that this affected the overall findings of our analysis given the small amount of lost data. Despite these limitations, our meta-analysis has several strengths compared to prior meta-analyses. First, we completed a thorough literature search to identify applicable trials, and this is the largest meta-analysis to date in terms of including the greatest number of subjects with ARDS. We also performed multiple subgroup analyses to minimize any influence on the results from studies with a risk of bias or low-quality evidence.

It is clear that lung-protective ventilation, optimal titration of PEEP, and minimization of sedation should be actively targeted and instituted for all patients with ARDS.² Currently, the use of NMBAs in patients with ARDS is given a weak recommendation in the guidelines published by the Society of Critical Care Medicine.³⁰ Use of NMBAs helps achieve physiologic benefit in hypoxemic subjects and has a short-term mortality benefit, but this does not translate into long-term benefits. Due to the risks of deep sedation and prolonged neuromuscular blockade, we cannot use NMBAs as a front-line adjunct therapy in all patients, and patients should be individually evaluated by clinicians to assess whether NMBAs are physiologically indicated. Nonpharmacologic strategies utilizing lung-protective ventilation and PEEP optimization should continue to be the backbone of ARDS management.² If patients with early, moderate-to-severe ARDS do not experience improvements in oxygenation or remain dysynchronous with the ventilator after 12 h of optimal nonpharmacologic treatment strategies, NMBAs should be considered.³¹