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Critical care
Original research
Mucoactive agents for acute respiratory failure in the critically ill: a systematic review and meta-analysis
  1. Rohan Anand1,
  2. Daniel F McAuley1,
  3. Bronagh Blackwood1,
  4. Chee Yap1,
  5. Brenda ONeill2,
  6. Bronwen Connolly1,3,4,
  7. Mark Borthwick5,
  8. Murali Shyamsundar1,
  9. John Warburton6,
  10. David van Meenen7,
  11. Frederique Paulus7,
  12. Marcus J Schultz7,8,9,
  13. Paul Dark10,
  14. Judy M Bradley1
  1. 1 Wellcome-Wolfson Institute for Experimental Medicine, Queen's University Belfast, Belfast, UK
  2. 2 Centre for Health and Rehabilitation Technologies, Institute of Nursing and Health Research, Ulster University, Newtownabbey, UK
  3. 3 Department of Physiotherapy, The University of Melbourne, Melbourne, Victoria, Australia
  4. 4 Lane Fox Respiratory Unit, Guy's and Saint Thomas' NHS Foundation Trust, London, UK
  5. 5 Oxford Critical Care, Oxford University Hospitals NHS Foundation Trust, Oxford, Oxfordshire, UK
  6. 6 Bristol Royal Infirmary, University Hospitals Bristol NHS Foundation Trust, Bristol, UK
  7. 7 University of Amsterdam, Academic Medical Center Department of Intensive Care Medicine, Amsterdam, Noord-Holland, Netherlands
  8. 8 Mahidol University, Mahidol Oxford Tropical Medicine Research Unit, Bangkok, Thailand
  9. 9 Nuffield Department of Medicine, Oxford University, Oxford, Oxfordshire, UK
  10. 10 Division of Infection, Immunity and Respiratory Medicine, NIHR Manchester Biomedical Research Centre, The University of Manchester, Manchester, UK
  1. Correspondence to Rohan Anand, Queen's University Belfast Wellcome-Wolfson Institute for Experimental Medicine, Belfast BT9 7BL, UK; ranand01{at}qub.ac.uk

Abstract

Purpose Acute respiratory failure (ARF) is a common cause of admission to intensive care units (ICUs). Mucoactive agents are medications that promote mucus clearance and are frequently administered in patients with ARF, despite a lack of evidence to underpin clinical decision making. The aim of this systematic review was to determine if the use of mucoactive agents in patients with ARF improves clinical outcomes.

Methods We searched electronic and grey literature (January 2020). Two reviewers independently screened, selected, extracted data and quality assessed studies. We included trials of adults receiving ventilatory support for ARF and involving at least one mucoactive agent compared with placebo or standard care. Outcomes included duration of mechanical ventilation. Meta-analysis was undertaken using random-effects modelling and certainty of the evidence was assessed using Grades of Recommendation, Assessment, Development and Evaluation.

Results Thirteen randomised controlled trials were included (1712 patients), investigating four different mucoactive agents. Mucoactive agents showed no effect on duration of mechanical ventilation (seven trials, mean difference (MD) −1.34, 95% CI −2.97 to 0.29, I2=82%, very low certainty) or mortality, hospital stay and ventilator-free days. There was an effect on reducing ICU length of stay in the mucoactive agent groups (10 trials, MD −3.22, 95% CI −5.49 to −0.96, I2=89%, very low certainty).

Conclusion Our findings do not support the use of mucoactive agents in critically ill patients with ARF. The existing evidence is of low quality. High-quality randomised controlled trials are needed to determine the role of specific mucoactive agents in critically ill patients with ARF.

PROSPERO registration number CRD42018095408.

  • critical care
  • ARDS
  • assisted ventilation
  • non invasive ventilation
http://creativecommons.org/licenses/by-nc/4.0/

This is an open access article distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited, appropriate credit is given, any changes made indicated, and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/.

https://doi.org/10.1136/thoraxjnl-2019-214355

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    Key messages

    What is the key question?

    • Do mucoactive agents improve clinically important outcomes in critically ill, ventilated patients with acute respiratory failure?

    What is the bottom line?

    • This systematic review found limited trials and evidence that mucoactives improved clinically important outcomes in patients ventilated with acute respiratory failure.

    Why read on?

    • We describe four mucoactive agents across 13 trials and explain why we urge mucoactive use with caution in this population.

    Introduction

    Acute respiratory failure (ARF) is a common cause of admission into intensive care units (ICUs) and is associated with high acute and late mortality rates.1–3 The mainstay of respiratory supportive therapy is invasive and non-invasive mechanical ventilation.4 A considerable proportion of patients within ICU are mechanically ventilated, with audit data from the USA suggesting up to 40% of patients may be receiving mechanical ventilation at any given time. In the UK, an estimated 116 000 adult ICU admissions alone are for respiratory support per annum.5

    Patients mechanically ventilated in the ICU for ARF can experience mucus accumulation due to several reasons including infection, muscle weakness, mucociliary escalator dysfunction and suppression of cough reflex due to analgesia and sedation used to facilitate ventilation.6 Targeted respiratory physiotherapy treatments, including mucoactive agents, are used to manage secretion retention.7 8 Mucoactive agents are a class of medications that aid the removal of mucus from the lung and are generally subclassified according to their mechanism of action.9 Mucolytics, such as N-acetylcysteine (NAC), work by breaking mucin crosslinking, mucoregulators such as carbocisteine decrease mucus production, expectorants such as hypertonic saline (HTS) work by increasing water content, and mucokinetics such as ambroxol work by increasing pulmonary mucus transport by acting on the cilia. This classification is not strict as it is known that some mucoactive agents, such as HTS, have multiple mechanisms of action.10 They can be delivered to patients either via inhalation direct to the lungs or systemically; oral or intravenous.

    There are no systematic reviews on the use of mucoactive agents in mechanically ventilated or high-flow nasal oxygen (HFNO) populations specific to ARF. Furthermore, the National Institute for Health and Care Excellence,11 the British Thoracic Society12 and the Intensive Care Society12 13 do not provide published recommendations regarding mucoactive agent use in this population. In contrast to the lack of evidence of efficacy, surveys show mucoactive agent usage is common14–16 with a recent survey of ICU- level practice finding mucoactive agents were used in 83% of ICU in the UK, although with notable variation in prescribing practices.17 This survey indicated high use of NAC, HTS and carbocisteine, with the most highly ranked indication for use being thick secretions, and the most widely expected benefit that of reduced duration of mechanical ventilation. Practice relating to the use of mucoactive agents is currently guided by anecdotal evidence, local experience and clinician preference.

    Objective

    To systematically review the current evidence for the use of mucoactive agents in critically ill patients with ARF, with the objective of determining improvement on clinically important outcomes.

    Methods

    Deviations between this review and protocol are listed in the online supplementary material.

    Supplemental material

    Types of studies

    We included any design of clinical trial that compared at least one mucoactive agent with standard care or placebo in ventilated patients (including HFNO) with ARF. We excluded observational, case series, pilot/feasibility and longitudinal studies.

    Types of participants

    We included trials that studied adults (at least 15 years old) who were mechanically ventilated, either invasively, non-invasively or had received HFNO for treatment of ARF. Invasive mechanical ventilation was defined as a participant requiring an artificial tracheal airway. Non-invasive ventilation was defined as application of respiratory support via a sealed face-mask, nasal mask, mouthpiece, or full face visor or helmet, without the need for tracheal intubation. HFNO was defined as any cannula sitting within the nostrils and delivering heated and humidified oxygen with a gas flow rate of ≥20 L/min.18 ARF was defined to include the following conditions: acute hypoxic respiratory failure (type 1), acute hypercapnic respiratory failure (type 2), acute respiratory distress syndrome (ARDS) and acute lung injury (ALI). Patients could present with one or more of these conditions. Patients with pre-existing chronic respiratory conditions with sputum abnormalities such as bronchiectasis or cystic fibrosis were excluded, however, patients with other chronic respiratory conditions including chronic obstructive pulmonary disease (COPD) were included.

    Types of interventions

    We included trials involving at least one mucoactive agent. A mucoactive agent was defined as any agent used to assist the removal of mucus/sputum from the lungs.9 19 We included any method of delivery as mucoactive mechanisms of action impact on the same clinical outcomes.20 We did not regard isotonic saline as an active mucoactive agent as it was used as the placebo/control group in several trials.

    Outcomes

    The primary outcome for invasive/non-invasive ventilated patients was duration of ventilation and for HFNO patients was intubation rate. Secondary outcomes were time to extubation, reintubation, number of ventilator free days at day 28, duration of ICU stay, duration of hospital stay, mortality (all cause within 28, 60 and 90 days), health-related quality of life, adverse events/development of other pathologies and healthcare related costs. All outcomes included were from a recently published core outcome set for trials of interventions intending to modify the duration of mechanical ventilation.21

    Search strategy

    We searched three electronic databases (MEDLINE, EMBASE, Cochrane Central Register of Controlled Trials), three clinical trial registries (EU Clinical Trial Register, ClinicalTrials.gov, WHO trial registry) and grey literature (OpenGrey). With the aid of a medical librarian, a comprehensive search strategy was developed using appropriate Medical Subject Headings (MeSH) and keywords (online supplementary material). The references of relevant articles were also checked for potentially eligible trials. All searches were from database inception to 9 January 2020. The search was for English language only articles.

    Data collection and analysis

    Search results were imported into a systematic review manager (Covidence: www.covidence.org) for screening and data extraction.

    Selection of studies

    Two review authors (RA and CY) independently screened titles and abstracts from the searches for inclusion. The full text of publications was retrieved for potentially eligible studies. Full-text publications were additionally also independently screened for inclusion by a third review author (DM) to confirm inclusion. Any disagreements or uncertainties were resolved through discussion or with consultation of the other review authors.

    Data extraction

    Data from included trials were extracted independently by two review authors (RA and CY) including: the type and setting of the study, number of participants, eligibility criteria (online supplementary material), nature of the intervention(s) in each group (dose and route of administration of mucoactive agent), time points of outcome measurement and results of outcomes. Any disagreements were resolved through discussion or with consultation of the other review authors. Study authors were contacted to request data that were not reported or insufficient in the main publication.

    Assessment of risk of bias

    Two review authors (RA and CY) independently used the Cochrane Risk of Bias tool for randomised trials within Covidence.22 Risk of bias was assessed across eight domains: sequence generation, allocation concealment, blinding of outcome assessors, blinding of participants, blinding of personnel, selective outcome reporting, incomplete outcome data and other sources of bias. Each potential source of bias was marked as high, low or unclear.

    Measures of effect

    The unit of analysis was the participant. Binary variables were calculated as odds ratios (ORs) with 95% confidence intervals (CIs). Continuous variables were calculated as mean differences (MDs) with 95% CIs. When analysing for mortality, we used the longest fully reported follow-up.23 Meta-analyses were performed using Review Manager V.5.3 and statistical heterogeneity evaluated using the I2 statistic, with a value of >50% implying substantial heterogeneity.24 Trials with standard care or a placebo as a comparator were grouped as ‘non-mucoactive agent’ and synthesised together. This was then compared with the pooled mucoactive group. We estimated mean values from trials that reported any relevant median values using methodologies from Wan et al.25 Analysis was undertaken using random methods models.

    For the NEBULAE trial (Effect of On-Demand vs Routine Nebulization of Acetylcysteine With Salbutamol on Ventilator-Free Days in Intensive Care Unit Patients Receiving Invasive Ventilation),26 the control group (routine nebulisation of a mucoactive agent) was regarded as the mucoactive agent group in the analyses and the ‘on-demand’ group was regarded as the control/standard care. The analyses compared the routine nebulisation group, that is, the intervention group to a subset of patients from the on-demand group that received no nebulisations, that is, the control group (n=268). This excluded patients that received NAC and salbutamol treatment in the control group. In the original trial, the control group was the routine nebulisation group, and the intervention group was the on-demand group.

    Subgroup analysis

    Where possible we performed meta-analysis based on specific mucoactive agent when there was adequate data. This included a subgroup analysis of mucoactive agent type for duration of ventilation, mortality and duration of ICU stay. There were insufficient trials to test subgroup differences in other outcomes.

    Sensitivity analysis

    Sensitivity analyses were not undertaken due to the small number of trials and a lack of aggregate data.27

    Quality of evidence

    Five authors (RA, JB, BB, BC and BO) determined an overall certainty of the evidence for the outcomes using the principles of the GRADE system (Grades of Recommendation, Assessment, Development and Evaluation) to rate the strength of findings into one of four levels: high, moderate, low or very low.28 We generated a ‘Summary of Findings’ table using GRADEpro software (www.gradepro.org) to present outcome-specific information regarding overall certainty of evidence from studies. Certainty of evidence was assessed according to study design, risk of bias, inconsistency, indirectness, imprecision, publication bias and any other factors, for example, confounding and downgraded by one (for serious) or two (for very serious) levels as necessary.

    Results

    Literature search

    The search identified 557 results (figure 1). After importing into covidence, five duplicates were identified and removed. After title and abstract screening, 510 records were excluded leaving 42 records for full text screening. After full-text screening, 13 completed trials were eligible for inclusion in the review26 29–40 with two trials identified as ongoing.41 42 A list of the 27 excluded studies, with reasons for exclusion, are within the online supplementary material. Also included within the online supplementary material are the numbers of search results found from each data resource.

    Figure 1
    Figure 1

    PRISMA flow diagram. PRISMA, Preferred Reporting Items for Systematic Reviews and Meta-Analyses.

    Study characteristics and risk of bias

    Characteristics of included trials are summarised in table 1. All studies were prospective randomised parallel group controlled trials, totalling 1712 patients. Mucoactive agents investigated included NAC (n=8 trials), heparin (n=3 trials), ambroxol (n=1 trial) and HTS (n=1). Nine trials included patients with ALI or ARDS, and four trials with a mixed ARF population. The number of participants in the trials ranged from 27 to 922. The longest follow-up was reported at 90 days. No trials involved patients receiving HFNO.

    View this table:
    Table 1

    Characteristics of included studies

    Risk of bias assessment is described in figure 2. Six trials26 29 30 33 36 40 were judged as high risk of bias in at least one domain, six trials31 32 34 35 37 39 were deemed as an unclear risk of bias across at least three domains and one trial36 overall had a low risk of bias. Ten trials29–37 39 had high or unclear risk of bias due to allocation concealment and nine29–32 34–37 39 due to sequence generation. Twelve26 29–37 39 40 trials had high or an unclear risk of bias due to blinding. All trials were at a low risk of attrition bias. One trial33 was at high risk of reporting bias.

    Figure 2
    Figure 2

    Risk of bias for included trials. (van Meenen 2018 had stated in their protocol that an economic analysis would be performed. This however was not within the trial publication. Following correspondence with authors this was a shared decision by them and the editor of JAMA. This cost related data is currently being used to prepare a separate publication to be submitted aside of the main clinical results. therefore, we assessed rob for selective outcome reporting as low.) HTS, hypertonic saline; NAC, N-acetylcysteine.

    Duration of mechanical ventilation

    The duration of mechanical ventilation was reported in seven trials26 29 31 34 37–39 (n=1226 patients). Pooled analysis showed no effect with the use of mucoactive agents with high heterogeneity (MD −1.34, 95% CI −2.97 o 0.29, p=0.11, I2=82%) (figure 3). There was no noticeable publication bias with funnel plot estimates (online supplementary material).

    Figure 3
    Figure 3

    Duration of ventilation. Forest plot of comparison: mucoactive agent versus placebo/standard care. HTS, hypertonic saline; IV, intravenous; NAC, N-acetylcysteine; Neb, nebuliser.

    Mortality

    Mortality was reported in 12 trials26 29–33 35–40 (n=1428 patients). Mucoactive agents had no effect on mortality (OR 0.75, 95% CI 0.52 to 1.08, p=0.12, I2=32%). Subgroup analysis showed no difference in reduction of mortality with use of NAC intravenous (OR 0.72, 95% CI 0.42 to 1.24, p=0.24, I2=3%), NAC neb (OR 0.98, 95% CI 0.55 to 1.74, p=0.94, I2=26%) or heparin (OR 0.89, 95% CI 0.50 to 1.58, p=0.69, I2=0%) all with low heterogeneity (figure 4). There was no noticeable publication bias with funnel plot estimates (online supplementary material).

    Figure 4
    Figure 4

    Mortality. Forest plot of comparison: mucoactive agent versus placebo/standard care. HTS, hypertonic saline; IV, intravenous; M-H, Mantel-Haenszel; NAC, N-acetylcysteine; Neb, nebuliser.

    Duration of ICU stay

    Duration of ICU stay was reported in 10 trials26 29 31 32 34 36–40 (n=1362 patients). There was a difference in duration of ICU stay favouring the use of mucoactive agents with high heterogeneity (overall MD −3.22, 95% CI −5.49 to 0.96, p=0.005, I2=89%). Subgroup analysis showed a difference in reduction of ICU stay with NAC intravenous with low heterogeneity (overall MD −4.70, 95% CI −7.92 to −1.48, p=0.004, I2=25%) and no difference in ICU stay with the use of nebulised heparin (overall MD −3.01, 95% CI −6.91 to 0.88, p=0.13, I2=85%) (figure 5). There was slight publication bias with funnel plot estimates (online supplementary material).

    Figure 5
    Figure 5

    Duration of ICU stay. Forest plot of comparison: mucoactive agent versus placebo/standard care. HTS, hypertonic saline; ICU, intensive care unit; IV, intravenous; NAC, N-acetylcysteine; Neb, nebuliser.

    Duration of hospital stay

    The duration of hospital stay was reported in four trials26 34 38 40 (1067=patients). Pooled analysis showed no difference with the use of mucoactive agents with high heterogeneity (overall MD −2.05, 95% CI −5.87 to 1.76, p=0.29, I2=81%) (figure 6).

    Figure 6
    Figure 6

    Duration of hospital stay. Forest plot of comparison: mucoactive agent versus placebo/standard care. IV, intravenous; NAC, N-acetylcysteine; Neb, nebuliser.

    Ventilator free days

    Three trials reported ventilator-free days, two at day 2826 40 and one trial reported at day 30.33 Pooled analysis showed no difference in the number of ventilator free days at day 28 with high heterogeneity (overall MD 2.35, 95% CI −1.76 to 6.45, p=0.26, I2=77%) (figure 7). For one study,33 the median number of ventilator free days was 11 for the mucoactive agent group and three for the placebo group. This study could not be incorporated into the meta-analysis as the mean (SD) could not be estimated.

    Figure 7
    Figure 7

    Ventilator free days at day 28. Forest plot of comparison: mucoactive agent versus placebo/standard care. IV, intravenous; NAC, N-acetylcysteine; Neb, nebuliser.

    Intubation rate, time to extubation, reintubation, health-related quality of life and healthcare-related costs

    No trials reported outcomes for intubation rate, time to extubation, reintubation, health-related quality of life or healthcare-related costs.

    Adverse events and development of other pathologies

    Three trials,26 33 38 investigating nebulised NAC, intravenous NAC and nebulised Heparin, respectively, reported on adverse events in both arms. Four further trials reported the number of adverse events only in the mucoactive agent arm of the study. Two trials analysed differences between groups. The NEBULAE trial26 reported that the proportion of patients developing one or more nebulisation-related adverse events was significantly higher in the mucoactive group that received nebulised NAC (p<0.001), however, the development of other pathologies/pulmonary complications were not significantly different between the two groups. One trial,29 investigating nebulised HTS, reported a significantly higher development of ventilator associated pneumonia in the control group, but did not report the original number of events in each arm (p=0.014). One trial40 investigating nebulised heparin reported no differences in number of days that patients had blood stained sputum. Further details on adverse events are summarised in the online supplementary material.

    Summary of findings

    Certainty of evidence is summarised in table 2. Downgrading of certainty levels was primarily related to high risk of bias and imprecision (high heterogeneity).

    View this table:
    Table 2

    GADE and summary of findings

    Discussion

    This systematic review found that use of mucoactive agents did not improve outcomes including duration of ventilation, mortality, duration of hospital stay or ventilator-free days at day 28, although they did decrease ICU stay. The GRADE evaluation showed that the certainty level of evidence for four outcomes in the review was very low, with only mortality having a moderate level of certainty of evidence. Certainty of the evidence was primarily impacted by a risk of bias mostly related to random sequence generation and allocation concealment. We note there are differences in our risk of bias assessment in some trials that were also included in a previous review, these are explained in the online supplementary material. Other reasons affecting the evidence included small sample size, mixed patient populations and high heterogeneity. Our findings indicate that further evidence is required to determine the effectiveness of mucoactive agents for critically ill patients with ARF. Future trials should be designed to address the methodological limitations identified in studies included in this review. Our systematic review echoes a previous expert narrative review in 2017 which concluded use of mucoactive agents within the critically ill is in need of evidence-based recommendations.19

    Two mucoactive agents that are used within critical care units, recombinant human DNase (also known as RhDNase) and carbocisteine were not investigated in trials in this review, therefore, highlighting the lack of evidence to support their use in ventilated patients with ARF. This mirrors findings from a review of aerosolised mucoactive agents in hospitalised patients43 and guidelines by The American Association for Respiratory Care,44 although these publications were not targeted at critically ill patients in the ICU. There is evidence of effect with these mucoactive agents in other respiratory conditions. Carbocisteine shows benefit for patients with COPD45 and RhDNase for cystic fibrosis.46 However, it should not be assumed that a mucoactive agent demonstrated to be effective in one clinical population will necessarily be effective in another population and indeed there may be potential for harm. For example, although there is evidence to support RhDNase in cystic fibrosis, a well-designed and powered clinical trial showed it was not effective and potentially harmful in a bronchiectasis population.47 We note that there is an active trial exploring the use of nebulised RhDNase in ventilated ARF patients. This trial aims to recruit 500 patients to explore the use of to reduce the incidence of ARDS.48 Expected to complete in 2021, it will likely provide evidence to guide the use of RhDNase.

    Eight trials in this review explored the effectiveness of intravenous NAC and a subgroup analysis highlighted that there was no benefit in mortality or duration of ventilation, however, there was a reduction in ICU stay. Our analysis of NEBULAE,26 with nebulised NAC, showed no improvement with outcomes with some evidence suggesting it may be associated with more adverse events. Our review supports the conclusions of a previous systematic review highlighting the need for more data to support use of NAC in the critically ill.49 Another review focusing on NAC use in ARDS also found a reduction of ICU stay based on three trials.50 However, they did not use the full core outcome set21 for ventilated trials or search for HFNO trials. There is a small ongoing trial expected to be complete later this year, exploring nebulised NAC in 52 ARDS patients.51

    The second most common mucoactive explored in this review was nebulised heparin, showing no improvement in clinical outcomes with the exception of one trial40 showing an improvement in ventilator free days. One trial that explored ambroxol showed improvements in duration of ventilation and reduced ICU and hospital stay. However, we acknowledge that ambroxol is not available in the UK. One trial29 exploring the efficacy of HTS showed significant reductions in mortality, duration of mechanical ventilation and ICU stay but this trial was small and methodologically flawed.

    Our recent survey of ICU unit level practice17 and a point prevalence survey52 exploring the use of mucoactive agents in ARF, showed HTS and carbocisteine are the most commonly used. Alongside this review, it provides justification for a clinical trial to explore the effectiveness of these mucoactive agents in ARF. These interventions could have adverse effects, and the resource use in terms of staff time to administer therapy, particularly those that are nebulised, may be significant. Conversely if any of these mucoactives have a positive significant impact on clinical outcomes there is also potential for savings such as reduced costs associated with shortened critical care and hospital stay. Also, these therapies are individually inexpensive, and a lack of robust evidence to support their use in practice may not deter some clinicians from continuing to prescribe them regardless of effectiveness. Nonetheless, as they are used in large numbers of critically ill patients, the overall scaled cost might be substantial.

    The strength of our review is that it followed prespecified methods using a published protocol (PROSPERO) with duplicate and independent screening and data extraction. We also obtained a subgroup of data from one large trial to strengthen the meta-analysis providing a more accurate estimate of effect and used a full core outcome set21 with a five member panel grading the quality of evidence for each outcome. The major limitations of the results are the relatively small number and large heterogeneity of included trials, the low quality of evidence, and lack of relevant reported outcomes and associated data. Not all trials reported fully on adverse events which leaves important questions surrounding the safety and tolerability of mucoactive agents.

    Conclusion

    In conclusion, the evidence in this review suggests that use of mucoactive agents does not improve most clinical outcomes in ventilated patients with ARF. The findings do not support the current widespread clinical practice of various mucoactive agents in mechanically ventilated patients with ARF. However, there was considerable heterogeneity in included trials and the certainty of this evidence is low. Therefore, until further evidence is available, mucoactive agent use should be considered with caution in this population. This systematic review justifies investment in large, high-quality randomised controlled trials to explore the use of commonly used mucoactive agents, where evidence does not already exist (eg, carbocisteine) or is not adequate (eg, HTS), to inform practice. Such trials should include appropriate outcomes from the core outcome set for ventilated trials21 and report fully on adverse events.

    Acknowledgments

    We would like to thank Rebecca Lancaster from Queen’s University Belfast for help with the translation and screening of German language papers. We also thank the NEBULAE investigators for providing subgroup data for their trial that was funded by a grant from The Netherlands Organisation for Health Research and Development (ZonMW). We would also like to acknowledge the Professor John Glover Award for support. Lastly we acknowledge previous publication of preliminary data via conference posters in abstract books (Anand R et al. Should mucoactives be used in acute respiratory failure in the critically ill? Results from a systematic review. 2019; Anand R et al. Should mucoactives be used in acute respiratory failure in the critically ill: preliminary results from a systematic review? 2018).

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    Footnotes

    • Contributors All authors fulfilled ICMJE guidelines for authorship criteria. RA, DM, JB, BB, CY, BO and BC contributed to the conception, data collection, data analysis, drafting the article and critical revisions. MB, MS and JW contributed to conception and provided critical revisions to the article. DvM, FP and MJS contributed to provisional data collection and critical revisions. PD provided critical revisions to the article.

    • Funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.

    • Competing interests JB, DM, BO and RA are investigators in an NIHR HTA funded trial of mucoactives in bronchiectasis.

    • Patient consent for publication Not required.

    • Provenance and peer review Not commissioned; externally peer reviewed.

    • Data availability statement All data relevant to the study are included in the article or uploaded as online supplementary information. Any additional details are available on reasonable request.

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