European Respiratory Society guidelines for the management of adult bronchiectasis

Recommendations

We suggest the minimum bundle of aetiological tests in adults with a new diagnosis of bronchiectasis (conditional recommendation, very low quality of evidence) is: 1) differential blood count; 2) serum immunoglobulins (total IgG, IgA and IgM); and 3) testing for allergic bronchopulmonary aspergillosis (ABPA).

It is expected that sputum culture is undertaken for monitoring purposes of bacterial infection. Mycobacterial culture may be helpful in selected cases where NTM are suspected as an aetiological cause of bronchiectasis. Additional tests may be appropriate in response to specific clinical features, or in patients with severe or rapidly progressive disease.

Summary of the evidence

The SEPAR and BTS guidelines have previously recommended a routine “bundle” of tests at diagnosis to identify possible underlying causes of bronchiectasis [37, 38]. Our systematic review identified no publications which directly addressed whether routine aetiological investigation protocols provide benefit compared to clinically driven investigations or no testing. Four observational studies were identified which describe the percentage of adult patients (7−37%) whose management changed following investigation of aetiology while no other relevant outcomes were reported [42–45].

Justification of the recommendation

Measurement of circulating white cell count and differential is suggested in all patients. The presence of lymphopenia or neutropenia may suggest primary or secondary immune deficiency, while lymphocytosis may suggest secondary immune deficiency as a consequence of haematological malignancy.

Serum IgA, IgM, IgG are generally tested together, and we have considered them jointly. Low IgG, with or without low IgM or low IgA may indicate a defective antibody production that is an important modifiable cause of bronchiectasis, and 2–8% of patients with bronchiectasis have common variable immune deficiency [42–44]. Importantly, in these cases immunoglobulin replacement treatment can result in significant improvement in short and long-term outcomes. The cost of serum immunoglobulin testing is low and testing is readily available.

The geographic distribution of ABPA is thought to be variable, but establishing diagnosis alters management [45]. Hence the panel advises routine screening of all patients for ABPA at diagnosis. The generally recommended screening tests for ABPA are total serum IgE, specific IgG to Aspergillus, and specific IgE to Aspergillus or, as an alternative, skin prick tests to Aspergillus [46, 47].

A range of other tests may be appropriate in specific circumstances. In patients with radiological features of NTM or clinical features such as weight loss, haemoptysis, rapid deterioration or symptoms non-responsive to standard therapy, three sequential daily sputum cultures for mycobacterial cultures or a single bronchoalveolar lavage should be considered [48]. Some authorities recommend measuring antibody responses to S. pneumoniae 23 valent polysaccharide vaccine (PPV23) in order to identify individuals with specific polysaccharide antibody deficiency [37, 38]. Failure to make an antibody response to PPV23 (four-fold increase in titre at 4–6 weeks) may suggest a defect in carbohydrate antigen responses. However, due to the large variability in individual antibody response to PPV23 and in testing protocols, this evaluation should not be performed without specialist support. Testing for cystic fibrosis with measurement of sweat chloride, other biomarkers of cystic fibrosis transmembrane conductance regulator (CFTR)-mediated chloride ion transport and CFTR gene mutation analysis should be considered in young adults or with specific clinical features of cystic fibrosis, such as upper lobe predominance of bronchiectasis on chest CT, the presence of nasal polyposis and/or chronic rhinosinusitis, recurrent pancreatitis, male primary infertility and/or malabsorption. Testing for primary ciliary dyskinesia with nasal nitric oxide, high-speed video analysis, transmission electron microscopy, immunofluorescence and/or genetic testing should be considered for patients with several of the following features: persistent wet cough since childhood, situs anomalies, congenital cardiac defects, nasal polyposis and/or chronic rhinosinusitis, chronic middle ear disease with or without hearing loss, a history of neonatal respiratory distress or neonatal intensive care admittance in term infants. Refer to the ERS guidelines for the diagnosis of primary ciliary dyskinesia for more information [49]. The presence of basal emphysema or early onset airflow obstruction could suggest the need to exclude alpha1-antitrypsin deficiency. There are a wide range of other causes of bronchiectasis many of which can be identified by history, physical examination and CT scanning. We do not recommend routine testing of autoantibodies to screen for connective tissue disease, but evidence of connective tissue disease should be sought by history and physical examination.

The suggested bundle is justified by the fact that, despite the lack of strong evidence, selected tests can considerably alter the clinical management of bronchiectasis by indicating specific therapeutic interventions such as immunoglobulin replacement, corticosteroids or antifungal treatment. These interventions imply significant potential benefits for some individuals, and minimal undesirable effects from testing for others. The patient advisory group reported that patients placed a high value on identifying the underlying cause of bronchiectasis.

Implementation considerations

The standard tests recommended in this bundle should be available in the majority of healthcare systems and should not present major implementation issues.

Recommendation

We suggest acute exacerbations of bronchiectasis should be treated with 14 days of antibiotics (conditional recommendation, very low quality of evidence).

Summary of the evidence

Bronchiectasis patients are typically given prolonged courses of antibiotics of 14 days' duration for infective exacerbations. This recommendation is given in previous guidelines for bronchiectasis [37, 38]. It is based on expert consensus and studies that documented good clinical outcomes with such treatment regimens. However, the evidence base for this duration is poor.

The published literature was assessed as to whether shorter (<14 days) courses of antibiotics would be as clinically effective or be associated with any harm compared to 14–21 days of therapy. There was no direct evidence of benefit favouring either 14–21 days or shorter courses of antibiotic therapy. The only data comes from an indirect comparison of response at day 7 versus day 14 in 53 patients, all receiving ciprofloxacin (with or without inhaled tobramycin) for 14 days. After pooling both study arms, bacterial load (MD: +0.23 cfu·mL^-1 higher at day 14, 95% CI −1.55 to +2.01) and forced expiratory volume in 1 s (FEV₁) (MD: +0.01 L at day 14, 95% CI −0.51 to +0.53) were similar at 7 and 14 days with wide confidence intervals including both benefit and harm. No data was available for clinical outcome such as subsequent quality of life and exacerbations (supplementary material) [50].

Data from other studies

Some authors have shown a favourable impact of 14 days of antibiotics for treatment of a bronchiectasis exacerbation. One study of 32 exacerbations treated with 14 days of intravenous antibiotics demonstrated significant improvement in 24-h sputum volume, bacterial clearance, C-reactive protein, incremental walk test and SGRQ, but no improvement in spirometry [51]. A further study of 34 patients treated with intravenous antibiotics for 14 days demonstrated a reduction in sputum bacterial load and markers of airway inflammation after antibiotic treatment [7].

Justification of the recommendations

In the absence of any direct data comparing longer and shorter courses of antibiotics, we suggest continuing the usual practice of treating acute exacerbations of bronchiectasis with 14 days of antibiotics on the basis of the patient's prior microbiology testing and the severity of the exacerbation. Patients have diverse views on the duration of antibiotics for exacerbations, with some preferring longer courses, and other patients wishing to use shorter courses if possible.

Implementation considerations

It is possible that shorter courses of antibiotics may be appropriate in some cases. The task force panel suggests that mild exacerbations, exacerbations in mild patients, those associated with pathogens more sensitive to antibiotics (e.g. S. pneumoniae), or patients with a rapid return to baseline state may benefit from shorter courses, but evidence supporting shorter course treatment is lacking. Otherwise, in patients with lack of recovery by 14 days of antibiotic therapy we suggest re-evaluation of the patient's clinical condition and a new microbiological investigation. Sending a sputum sample at the start of an exacerbation is helpful to guide choice of antibiotics in the event of inadequate response to initial therapy. Due to variations in antibiotic use and healthcare practices across Europe, we do not address choice of specific antibiotics, or the role of combination versus monotherapy in this guideline.

Further research studies assessing the optimal duration of antibiotics are recommended.

Recommendations

We suggest that adults with bronchiectasis with a new isolation of P. aeruginosa should be offered eradication antibiotic treatment (conditional recommendation, very low quality of evidence).

We suggest not offering eradication antibiotic treatment to adults with bronchiectasis following new isolation of pathogens other than P. aeruginosa (conditional recommendation, very low quality of evidence)

Summary of the evidence

Eradication treatment refers to any antibiotic treatment given with the express intention of achieving complete clearance of the pathogen from the airway. In bronchiectasis, eradication treatment regimens vary, but there is some evidence suggesting that a regimen including a nebulised antibiotic achieves greater rates of clearance and clinical benefits than intravenous treatment alone in achieving clearance of P. aeruginosa [52].

Chronic airway infection in adult patients with bronchiectasis is frequent and usually associated with worse outcomes such as more exacerbations and poorer quality of life [15, 53]. Definitions of chronic airway infection in bronchiectasis are not established but a systematic review identified that the most frequent definition used in bronchiectasis studies is two or more isolates of the same organism at least 3 months apart in 1 year [15]. Unfortunately, in patients with persistent infections, there is little evidence about the beneficial effects of pathogen eradication beyond P. aeruginosa.

We could not identify any randomised controlled trial directly addressing the question. Therefore we included two studies that investigated whether eradication treatment in adult patients with bronchiectasis improved clinical outcomes compared to the patient's own baseline [54, 55]. Pooled analysis provides some evidence of the potential benefits of P. aeruginosa eradication in terms of negative sputum samples, frequency of subsequent exacerbations and quality of life, but the evidence is indirect and considered of low quality.

In particular, the retrospective observational study of White et al. [55] analysed different eradication treatment regimens: i.v. antibiotics (12 cases), i.v. antibiotics followed by inhaled antibiotics (13 cases), and oral ciprofloxacin alone. 25 patients across all groups received 3 months of inhaled colistin. Initial clearance rate from sputum was 80%, but 54% of all patients remained P. aeruginosa free at follow-up and the exacerbation rate fell from 3.93 to 2.09 per year after the eradication treatment. In addition, two thirds of patients experienced clinical improvement although lung function remained unchanged.

Orriols et al. [54] performed a 15-month single-masked, randomised controlled trial in 35 patients with early P. aeruginosa infection. These patients received initial therapy with i.v. ceftazidime or tobramycin followed by 3 months of 300 mg of nebulised tobramycin b.d. or placebo. At the end of follow-up (12 months), 54% of patients were free of P. aeruginosa in the tobramycin group versus 29% in the placebo group. Despite some potential methodological limitations, this study showed that the median time to recurrence of P. aeruginosa was longer in the treatment arm compared to placebo and numbers of exacerbations and hospital admissions were lower in the nebulised tobramycin group. The impact of eradication treatments on the development of antibiotic resistance was not extensively studied. This study had no control group and so is limited in terms of informing whether eradication is effective.

There is no clear evidence to support one regimen over another, and therefore figure 3 illustrates some commonly used regimes.

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FIGURE 3

Three possible and alternative eradication treatment pathways based on what is commonly used in clinical practice. After each step it is recommended to repeat sputum sampling for Pseudomonas aeruginosa and to progress to the next step if the culture remains positive.

Justification of the recommendation

The poor clinical outcomes associated with chronic P. aeruginosa infection, the data from one observational study and the clinical experience in cystic fibrosis suggests that P. aeruginosa eradication may positively influence important clinical outcomes including exacerbation frequency.

There is no evidence to support eradication of organisms other than P. aeruginosa and in organisms that are not so clearly associated with poorer outcomes, the risk-benefit ratio is less in favour of eradication treatment.

Implementation considerations

Identification of new isolates of P. aeruginosa requires regular sputum surveillance which has resource implications. We suggest as a minimum that patients should have a sputum sample sent when clinically stable once per year. In circumstances where the date of acquisition of P. aeruginosa is uncertain, a clinical judgement must be made on the likely success or otherwise of an eradication attempt. This guideline does not address attempted eradication of chronic P. aeruginosa infection, where the infection has been present for many years, as this is thought unlikely to be successful. The quality of evidence is low and further research is also needed on potential side effects of eradication therapies and, particularly, the emergence of resistance or new infections.

Recommendation:

We suggest not offering treatment with inhaled corticosteroids to adults with bronchiectasis (conditional recommendation, low quality of evidence).

We recommend not offering statins for the treatment of bronchiectasis (strong recommendation, low quality of evidence).

We suggest that the diagnosis of bronchiectasis should not affect the use of inhaled corticosteroids in patients with comorbid asthma or COPD (best practice advice, indirect evidence).

We considered only studies of anti-inflammatory drugs that were at least 3 months in duration. Although macrolides may have anti-inflammatory activity their role in bronchiectasis is discussed within PICO question 5 of these guidelines (regarding antibiotics). We identified six systematic reviews [56–61] and three studies that met our inclusion criteria [62–64].

Hernando et al. [64] reported a double-blind randomised controlled trial over 6 months with 77 patients allocated to inhaled budesonide 400 μg b.d. or placebo with a primary outcome of lung function. Tsang et al. [62] reported a trial of inhaled fluticasone versus placebo over 12 months in 86 patients with co-primary end-points of 24 h sputum volume and annual exacerbation frequency. Mandal et al. [63] studied atorvastatin in 30 patients over 6 months compared to a matched group receiving placebo with a primary outcome improvement in cough related quality of life measured by the Leicester cough questionnaire. Overall the three studies included only 193 patients. Two of the studies assessed the effects of anti-inflammatories on exacerbations with a wide confidence interval (rate ratio (RR) 0.99, 95% CI 0.76–1.30) [62, 64]. Hence no clear benefit on reducing exacerbations was noted.

The effect on quality of life, using the SGRQ, was only reported in two studies (123 patients) [63, 64], with an observed improvement of 0.91 points (below the minimal clinically significant difference of 4 points, 95% CI −4.51 to +6.33). All three studies reported FEV₁ and forced vital capacity (FVC) as lung function outcomes [62–64]. No significant benefit was seen with any of the treatments studied for lung function.

The study design and small number of patients make these studies not optimal for safety assessment. Across the three studies the pooled estimate of suffering any adverse event was RR 2.75 (95% CI 1.21–6.25) as compared to control. The adverse effect profile of both inhaled corticosteroids and statins has been well described.

The increase in pooled adverse events was largely driven by Mandal et al. [63] who reported that adverse events led to withdrawal from the atorvastatin group (one case of headache, one of diarrhoea, and two of combined diarrhoea and headache). One was withdrawn due to liver function abnormalities at 3 months. 10 (33%) patients receiving atorvastatin had an adverse event versus three (10%) allocated placebo (difference 23%, 95% CI 3–43; p=0.02).

For the inhaled corticosteroid trials in bronchiectasis, adverse event reporting was incomplete. Known and frequent local adverse events across all diseases include dysphonia and oropharyngeal candidiasis. More severe adverse events include: alteration of the hypothalamic-pituitary-adrenal axis function, pneumonia, increased intraocular pressure, formation of cataracts and decreased bone density.

Justification of recommendations

There are no large trials of anti-inflammatory therapies in bronchiectasis and the existing studies show minimal and, in most cases, no clinically significant benefits. The increased frequency of adverse events, particularly with statins, justifies a recommendation against their use. The guideline panel concludes that inhaled corticosteroids do not have a role in the routine management of bronchiectasis. Inhaled corticosteroids have an established role in the treatment of asthma and a proportion of patients with COPD. In the absence of specific data in adult patients with bronchiectasis and these two conditions, the guideline panel concludes that the presence of bronchiectasis alone should not lead to a decision to withdraw inhaled corticosteroids from patients with established asthma or COPD.

Implementation considerations

We recommend randomised controlled trials of inhaled corticosteroids in bronchiectasis who are naïve to inhaled corticosteroid therapy. Inhaled corticosteroid use is, however, already widespread in bronchiectasis. In those already treated with inhaled corticosteroids and no clear history of asthma or COPD a randomised controlled trial of inhaled corticosteroid withdrawal may help define true utility of this widely prescribed therapy.

Recommendations

We suggest offering long-term antibiotic treatment for adults with bronchiectasis who have three or more exacerbations per year (conditional recommendation, moderate quality evidence).

All subsequent recommendations refer to patients with three or more exacerbations per year.

We suggest long-term treatment with an inhaled antibiotic for adults with bronchiectasis and chronic P. aeruginosa infection (conditional recommendation, moderate quality evidence).

We suggest long-term treatment with macrolides (azithromycin, erythromycin) for adults with bronchiectasis and chronic P. aeruginosa infection in whom an inhaled antibiotic is contraindicated, not tolerated or not feasible (conditional recommendation, low quality evidence).

We suggest long-term treatment with macrolides (azithromycin, erythromycin) in addition to or in place of an inhaled antibiotic, for adults with bronchiectasis and chronic P. aeruginosa infection who have a high exacerbation frequency despite taking an inhaled antibiotic (conditional recommendation, low quality evidence).

We suggest long-term treatment with macrolides (azithromycin, erythromycin) for adults with bronchiectasis not infected with P. aeruginosa (conditional recommendation, moderate quality evidence).

We suggest long-term treatment with an oral antibiotic (choice based on antibiotic susceptibility and patient tolerance) for adults with bronchiectasis not infected with P. aeruginosa in whom macrolides are contraindicated, not tolerated or ineffective (conditional recommendation, low quality evidence).

We suggest long-term treatment with an inhaled antibiotic for adults with bronchiectasis not infected with P. aeruginosa in whom oral antibiotic prophylaxis is contraindicated, not tolerated or ineffective (conditional recommendation, low quality of evidence).

We identified eight systematic reviews [65–72] and 17 relevant studies for this clinical question [36, 52, 73–86]. Our evidence summary suggests that long-term antibiotic use, pooling both inhaled and oral antibiotic data, reduces the number of exacerbations, time to first exacerbation, sputum purulence and breathlessness in adults with bronchiectasis; however, they are also associated with more adverse events and bacterial resistance.

Three randomised controlled trials evaluating the effect of nebulised antibiotics in adults with bronchiectasis suggested beneficial effects on exacerbation frequency and/or time to first exacerbation [65, 76, 78, 83]. In a study involving 144 adults with bronchiectasis and P. aeruginosa infection, colistin 1MU delivered twice daily through the I-neb was not associated with a statistically significant improvement in time to first exacerbation compared to placebo [83]. However, in a pre-planned analysis in adherent individuals (defined as taking ≥81% of doses recorded by the I-neb), the median (25th quartile) time to exacerbation was 168 (65) days versus 103 (37) days in the colistin and placebo groups, respectively (p=0.038). A similar treatment effect was reported in a study evaluating nebulised liposomal ciprofloxacin in 42 adult patients with bronchiectasis and P. aeruginosa infection [78]. A 12-month single blind study of nebulised gentamicin in 65 adults with bronchiectasis predominantly infected with H. influenzae (n=26, 46%) or P. aeruginosa (n=24, 42%) showed significant benefits including fewer exacerbations compared to 0.9% saline-treated patients [76].

Three randomised controlled trials showed beneficial effects of macrolide antibiotics (azithromycin or erythromycin) on exacerbation frequency in adults with bronchiectasis: EMBRACE (141 patients on azithromycin or placebo for 6 months) [77], BAT (83 patients on azithromycin or placebo for 12 months) [80] and BLESS (117 patients on erythromycin or placebo for 12 months) [79]. The EMBRACE study showed the rate of event-based exacerbations was 0.59 per patient in the azithromycin group and 1.57 per patient in the placebo group in the 6-month treatment period (RR 0.38, 95% CI 0.26–0.54; p<0.0001); the BAT study showed the median (interquartile range) number of exacerbations in the azithromycin group was 0 (0–1), compared with 2 (1–3) in the placebo group (p<0.001); and the BLESS study showed erythromycin significantly reduced protocol defined exacerbations compared to placebo (mean 1.29, 95% CI 0.93–1.65 versus 1.97, 95% CI 1.45–2.48 per patient per year; p<0.003). Doses used in clinical trials or in clinical practice range from 250 mg azithromycin daily, 500 mg or 250 mg three times per week, and erythromycin 400 mg twice daily.

Historical randomised controlled trials evaluating penicillin and tetracycline based antibiotic regimens also suggest some benefit in adults with bronchiectasis, with two long-term studies reporting less days off work and reduced sputum purulence with oxytetracycline [84] or amoxicillin treatment [73].

Important adverse events were reported with long-term antibiotic treatment. Diarrhoea was more common with oral antibiotics than placebo in the macrolide studies, although treatment discontinuation was rare [66–70]. There was also a 28% increase in the proportion of macrolide-resistant commensal oropharyngeal Streptococci after 12 months treatment with erythromycin and a macrolide resistance rate of 88% following 12 months of azithromycin [79, 80]. In contrast, there was no antimicrobial resistance reported after 6–12 months of nebulised colistin, dual release liposomal ciprofloxacin or gentamicin [76, 78, 83]. While these specific nebulised preparations were well tolerated, two phase III trials reported more frequent treatment-related adverse events (1.4 and 1.8 times greater) and discontinuations (2.1 and 6.7 times greater) associated with nebulised aztreonam compared to placebo [36]. The most commonly reported adverse events were breathlessness, cough and increased sputum production. The incidence of potential treatment-related adverse events such as QTc prolongation with macrolides, tinnitus/hearing loss with macrolides and inhaled aminoglycosides, and renal dysfunction with inhaled aminoglycosides is not known in people with bronchiectasis, but should be considered when weighing up the potential benefits and harms of long-term antibiotic treatment.

Justification of recommendations

The overall balance of desirable effects (particularly fewer exacerbations), undesirable effects (particularly gastrointestinal upset and antimicrobial resistance) and patient values favours long-term antibiotic treatment in selected patients (figure 4). For individuals with P. aeruginosa, the currently available evidence supports continuous use of nebulised colistin [83] or gentamicin [76]). Nebulised aztreonam is not recommended due to the lack of efficacy with regard to quality of life improvement over two treatment cycles and a high adverse event rate reported in the pivotal phase III trials [36]. Due to the relatively low number of participants with P. aeruginosa in the macrolide studies, the use of macrolide antibiotics is suggested as a second-line option in patients with this organism [77, 79, 80]. However, for individuals with no evidence of P. aeruginosa infection, macrolide treatment is suggested as first-line treatment due to the high-quality evidence for exacerbation reduction and an acceptable side-effect profile [77, 79, 80].

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FIGURE 4

Summary of recommendations for long-term antibiotic treatment.

Although the macrolide studies included a minimum exacerbation frequency of one [77], two [79] or three [80] exacerbations in the year preceding enrolment as an entry criterion, the mean exacerbation frequency in the year prior to enrolment in each of the three studies was ≥3. Due to potential undesirable effects, the suggested threshold for starting long-term antibiotic treatment is ≥3 exacerbations per year. However, this threshold may be reduced for individuals with: a history of severe exacerbation, relevant comorbidities such as primary/secondary immunodeficiency, patients in whom exacerbations are having a significant impact on their quality of life or those with more severe bronchiectasis [9].

Before considering the prescription of long-term antibiotics, general aspects of bronchiectasis management need to be optimised, such as airway clearance and treating modifiable underlying causes. Careful characterisation of sputum pathogens (bacteria, mycobacteria and fungi) before and after implementation of long-term antibiotics is essential to direct antibiotic choices, monitor resistance patterns and identify treatment emergent organisms. Drug toxicity monitoring is also required, most notably with macrolides and inhaled aminoglycosides.

Implementation considerations

The use of inhaled antibiotics is associated with a 10–32% risk of bronchospasm [76, 87] and a supervised test dose with pre- and post-spirometry is recommended. Prior inhalation of a short-acting bronchodilator may prevent bronchospasm and, therefore, is advisable.

Prior to long-term treatment with macrolides, we recommend excluding active NTM infection because macrolide monotherapy can increase the risk of macrolide resistance in NTM.

No cost-effectiveness studies were identified regarding the use of long-term antibiotics in adult patients with bronchiectasis and further research will be required to determine if cyclical or continuous treatment (possibly involving combinations of preparations) is optimal in terms of exacerbation frequency reduction, treatment burden and risk of antimicrobial resistance.

Figure 4 summarises the approach to long-term antibiotic treatment in adults with bronchiectasis summarising the above guideline recommendations.

Recommendation

We suggest offering long-term mucoactive treatment (≥3 months) in adult patients with bronchiectasis who have difficulty in expectorating sputum and poor quality of life and where standard airway clearance techniques have failed to control symptoms (weak recommendation, low quality evidence).

We recommend not to offer recombinant human DNase to adult patients with bronchiectasis (strong recommendation, moderate quality evidence)

Summary of the evidence

Airway clearance adjuncts such as mucolytics and hyperosmolar agents alter mucus viscosity and/or enhance mucociliary clearance. We identified three systematic reviews [88–90] and five relevant studies meeting inclusion criteria for this clinical question [35, 91–94]. Of these five randomised controlled trials, two were performed with dry powder mannitol at doses of 320 mg (n=343) [93] and 400 mg twice daily (n=461) [94], one with nebulised recombinant human DNase at a dose of 2.5 mg twice daily (n=349) [35], and two with nebulised hypertonic saline (one with 4 mL 7% once daily [91] or 5 mL 6% twice daily [92], n=28 and n=40 respectively). Only in two studies [35, 93] was the treatment compared to placebo. In one study with mannitol [94] and in both studies with hypertonic saline [91, 92], the treatment was compared to low dose mannitol (50 mg twice daily) [94] and isotonic saline [91], respectively. Three previous meta-analyses of mucoactive and inhaled hyperosmolar agents in bronchiectasis prior to the most recent mannitol study [93] found insufficient evidence to draw firm conclusions on the effect of inhaled mucoactive and hyperosmolar treatment due to the significant differences in methodology, patient groups and findings amongst the limited data available [88–90].

Patients with ≥2 exacerbations in the previous year and a baseline minimum SGRQ score of 30 who received mannitol showed a significantly greater improvement in total SGRQ score compared to controls (low dose mannitol), although the difference between arms did not reach the minimal clinically important difference for the total SGRQ score [93]. An improvement in SGRQ components was shown in patients without chronic P. aeruginosa infection and with no long-term antibiotic treatment who received hypertonic saline 7% [92].

None of the mucoactive agents significantly reduced the number of exacerbations, and the exacerbation rate was higher in the rhDNase group compared with placebo [35]. In patients with ≥2 exacerbations in the previous year, mannitol increased the time to first exacerbation [94]. In one study with hypertonic saline 7% there were reductions in health care utilisation when comparing prospectively collected data between hypertonic saline and isotonic saline phases [92].

In four studies, a tolerance test was performed at first administration: patients with mannitol-induced bronchospasm (16%) [93, 94] or a decrease in FEV₁ of more than 10% [92] or 15% [91] after inhalation of hypertonic saline (7% and 6%, respectively) were excluded.

In the 3-month study, 1.8% of patients randomised to mannitol experienced bronchospasm and 1.3% reported dyspnoea as opposed to none in the placebo group [93]. In the 13-month study, 20.2% of patients in the mannitol arm and 16.7% in the control group experienced adverse events related to study medication, most of which were judged to be mild or moderate [94]. Hypertonic saline was well tolerated with the number of patients with adverse events similar to those of the control groups.

The mannitol studies both showed a significantly increased 24 h sputum weight after treatment compared to the control arms, consistent with improved mucociliary clearance [93, 94]. Mean 24 h sputum weight decreased progressively during the study in both mannitol and control arms of both studies, but remained higher in the mannitol arms throughout.

No change in lung function was observed in the studies with mannitol [93, 94] or hypertonic saline 6% [91]. However, a significant improvement in FEV₁ and FVC was shown with hypertonic saline 7% at 3 months [92]. In contrast, a decrease in FEV₁ was demonstrated in patients treated with RhDNase.

There is insufficient evidence to permit evaluation of the use of oral mucolytics such as carbocisteine for bronchiectasis [89].

Justification of the recommendation

In summary, despite the wide heterogeneity in studies (agent used, study design and treatment duration), overall the literature showed a small improvement in the time to first exacerbation with a slightly elevated but acceptable adverse event profile with inhaled long-term mucoactive agents. The reported improvements in quality of life indicate that a proportion of patients will experience a significant benefit with these agents, but many patients will not.

The current research evidence and the ELF/EMBARC bronchiectasis patient advisory group suggest that patients give intermediate value to this treatment and acknowledge difficulties with its administration. Mucoactive therapy is time-consuming and the therapeutic equipment, in the case of nebulisers, may be difficult to take outside of the patient's home.

Implementation considerations

The indication and type of treatment given should be tailored to each individual patient according to their baseline symptom profile (frequency and severity of exacerbations, quality of life, bronchial hyperreactivity, and sputum viscosity), baseline lung function and patient preferences. We suggest testing tolerance prior to starting therapy and to consider beta-agonist premedication.

Larger studies should be considered in the future to investigate optimal treatment, dosages, durations and combinations.

Recommendations

We suggest not routinely offering long-acting bronchodilators for adult patients with bronchiectasis (conditional recommendation, very low quality of evidence)

We suggest to offer long acting bronchodilators for patients with significant breathlessness on an individual basis (weak recommendation, very low quality of evidence).

We suggest using bronchodilators before physiotherapy, inhaled mucoactive drugs, as well as before inhaled antibiotics, in order to increase tolerability and optimise pulmonary deposition in diseased areas of the lungs (good practice point, indirect evidence).

We suggest that the diagnosis of bronchiectasis should not affect the use of long acting bronchodilators in patients with comorbid asthma or COPD (good practice point, indirect evidence) [95, 96].

Where multiple inhaled therapies are used in the same patient, the sequence of treatments shown in figure 5 is commonly used by members of the task force.

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FIGURE 5

Flowchart of multiple sequential airways treatment administration in adult patients with bronchiectasis.

Summary of the evidence

Very limited and indirect evidence is available for the benefit of the long-term treatment with bronchodilators from a systematic review that included a single trial, comparing high-dose inhaled corticosteroids to medium-dose inhaled corticosteroid/long acting beta-agonist combination [97]. The results from this study indicate some positive effects on symptom control/symptomatic improvement, in particular decreased dyspnoea, better cough control, better health-related quality of life (measured by SGRQ symptoms domain), and reduced use of β₂-agonist rescue medication. Specific side-effects were generally mild (tremor, nervousness and tachycardia). A systematic review identified major methodological and reporting concerns relating to this trial [56]. However, extrapolating evidence from populations with other obstructive airway diseases some bronchiectasis subpopulations may benefit from bronchodilators, in particular subjects with chronic obstructive airflow limitation (FEV₁/FVC <0.7; with or without FEV₁ reversibility to bronchodilators), or associated asthma in combination with inhaled corticosteroids [95, 96].

Justification of the recommendations

We suggest the use of bronchodilators in patient with significant breathlessness due to the feasibility of application, the easy availability at a primary care level, the comparatively low treatment costs, and a putatively positive ratio of benefits to adverse events. Appropriate inhalation device selection and inhaler technique training are recommended. If treatment with bronchodilators does not result in a reduction in symptoms it should be discontinued. There is no evidence to support the use of bronchodilators routinely as part of the management of bronchiectasis patients without symptomatic breathlessness. According to both research evidence and patient advisory group feedback, it seems that patients regard this as a low risk and low burden intervention.

Implementation considerations

The intervention is easy to administer and acceptable to the majority of patients. Further investigator-driven research on the benefit of bronchodilators in bronchiectasis in various clinical situations is needed.

Recommendation

We suggest not offering surgical treatments for adult patients with bronchiectasis with the exception of patients with localised disease and a high exacerbation frequency despite optimisation of all other aspects of their bronchiectasis management (weak recommendation, very low quality of evidence).

Summary of the evidence

The rationale for surgical treatment of bronchiectasis is to break the vicious circle of bronchiectasis by removing the lung segments that are no longer functional, and preventing the contamination of adjacent lung zones. The most frequent indication for the operation is recurrent infections with chronic symptoms such as productive cough, purulent sputum and haemoptysis [98, 99].

Lobectomy is the most frequently performed operation, but numerous options have been described (e.g. segmentectomy and pneumonectomy) [100–102]. Surgery is the procedure of choice for massive haemoptysis refractory to bronchial artery embolisation, but emergency surgery in unstable patients is associated with higher morbidity and mortality reaching 37% [103]. Although bilateral bronchiectasis (reported in 5.8 to 30% of surgical series) are not an absolute contraindication for surgery [104], other options such as prolonged conservative treatment or bronchial artery embolisation are frequently used as an alternative. The video-assisted thoracoscopic surgery (VATS) is often preferred to better preserve lung function or reduce scarring. In comparison with open surgery, VATS has been reported to produce comparable symptomatic improvement (94 versus 88%), but with shorter hospital stay, fewer complications (17.5 versus 23.7%) and less pain after VATS procedures [105]. Contraindications to VATS include major parenchymal or pleural fibrosis, and calcified nodes close to the hilar vessels.

No randomised controlled trials of surgical treatment versus standard care were identified. A meta-analysis included 38 observational studies with 5541 patients, dealing with efficacy and safety of different surgical interventions for adult patients with bronchiectasis focused on three main outcomes: mortality, morbidity (adverse events) and quality of life improvement (symptomatic changes defined as reduction or alleviation of preoperative symptoms) [98].

The pooled mortality from 29 studies that focused on adult patients was 1.4% (95% CI 0.8%–2.5%) [98]. Post-operative pooled morbidity for adults was analysed in 26 observational studies and was 16.2% (95% CI,12.5%–19.8%) [98]. It needs to be emphasised that there are no data comparing morbidity to continued medical non-surgical management alone. Moreover, according to the aforementioned studies, some of the morbidity is considered relatively minor (air leak, atelectasis, wound infection). Symptomatic changes were analysed in 26 observational studies. In the pooled meta-analysis, complete alleviation of symptoms was seen in 71.5% (95% CI 68–74.9) and reduction of preoperative symptoms was seen in 20.2% of the adult population (95% CI 17.3–23.1) [98]. Other research has shown that extent of residual bronchiectasis and P. aeruginosa infection were reported as unfavourable prognostic factors [99].

Justification of the recommendations

Overall, surgical interventions seem to be beneficial only in very carefully selected patients requiring the best risk-benefit profile of improved symptoms against the morbidity associated with surgery. Feedback from the ELF/EMBARC patient advisory group suggests that patients would choose surgery only if there was no effective medical option for treatment and this feedback informs the recommendation.

Implementation considerations

Involvement of an experienced surgeon in partnership with an expert respiratory physician is advisable if surgical treatment is being considered. Attention should be paid to pre-operative nutritional status and pulmonary rehabilitation. More research is needed on surgical interventions. Although a randomised trial would be very challenging future studies should include a matched control population with meticulous description of other treatments used in both populations.

Recommendations

We suggest that patients with chronic productive cough or difficulty to expectorate sputum should be taught an airway clearance technique (ACT) by a trained respiratory physiotherapist to perform once or twice daily (weak recommendation, low quality of evidence).

We recommend that adult patients with bronchiectasis and impaired exercise capacity should participate in a pulmonary rehabilitation programme and take regular exercise. All interventions should be tailored to the patient's symptoms, physical capability and disease characteristics (strong recommendation, high quality of evidence).

Summary of the evidence (figure 6)

In bronchiectasis, it is a common belief that physiotherapy can improve mucus clearance and reduce lung inflammation and risk of infection. In addition, it is well accepted by patients. Respiratory physiotherapy includes ACTs and pulmonary rehabilitation [106, 107]. ACTs consist of breathing techniques, e.g. active cycle of breathing and autogenic drainage, sometimes combined with an instrument, e.g. flutter or Acapella, that modify expiratory flow and volumes or produce chest wall oscillations in order to increase mucus clearance [108–112]. The principal effect obtained by ACTs is an increase in sputum volume [108, 112, 113] and a reduced impact of cough on quality of life [109, 114]. Interesting, but still preliminary data, shows reduced peripheral airways obstruction, less inflammatory cells in sputum and improved exercise capacity after ACTs [109, 112, 114]. The aim of a pulmonary rehabilitation programme is to improve exercise tolerance and quality of life through a tailored standardised exercise protocol [115–117].

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FIGURE 6

Chest physiotherapy interventions flow chart based on clinical experience from the task force panel. AD: autogenic drainage; ELTGOL: total slow expiration with open glottis and infralateral position; ACBT: active cycle of breathing techniques; PEP: positive expiratory pressure; T-PEP: temporary positive expiratory pressure; HFCWO: high frequency chest wall oscillation.

We identified three systematic reviews [106, 118, 119] and several additional trials. We included a total of 14 clinical trials in our analysis [91, 108, 110–112, 114–117, 120–124].

The pooled analysis shows that pulmonary rehabilitation has a clear impact on exercise capacity immediately after the programme and a nonsignificant trend to improved quality of life (SGRQ) [116, 117, 119, 122, 123]. However, the unpooled study of Mandal et al. [122] (pulmonary rehabilitation duration (8 weeks) shorter than for pooled studies) described that improvements on exercise capacity and patient's quality of life may be maintained for a longer period of time. Finally, there is one publication showing an impact of pulmonary rehabilitation (8 weeks of supervised exercise training and review of ACTs) decreasing the frequency of exacerbations (median 1 (interquartile range 1–3) versus 2 (1–3); p=0.012) over 12-month follow-up and longer time to first exacerbation (8 versus 6 months; p=0.047) [116]. The reported impact of both ACTs and pulmonary rehabilitation on pulmonary function is not clinically important [107–109, 112, 121].

Justification of the recommendations

The evidence for airways clearance techniques is weak because the studies are small and poorly comparable due to methodological issues. However, most studies demonstrated a significant increase of sputum volume. The evidence is stronger for pulmonary rehabilitation, showing improvements in exercise capacity, cough symptoms and quality of life, and possibly a reduction in exacerbations. The benefits of pulmonary rehabilitation are achieved in 6 to 8 weeks and maintained for between 3 to 6 months. Finally, there are no relevant adverse effects and the bronchiectasis patients advisory group value the intervention.

Implementation considerations

The research priorities in physiotherapy are: larger controlled studies with clinical outcomes (exacerbations, cough and quality of life); larger controlled studies including physiotherapy training plus mucoactive agents such as hypertonic saline; the role of pulmonary rehabilitation on exacerbations; and finally, the compliance with these interventions over a longer period of time (>12 months) [125].