European Respiratory Society guidelines for the management of children and adolescents with bronchiectasis

Recommendation

• In children/adolescents with bronchiectasis, we recommend they are taught and receive regular ACT or manoeuvres. (Strong recommendation, low quality of evidence.)

Remarks: Individualised ACT that are development- and age-appropriate are best taught by a paediatric-trained chest physiotherapist (figure 2). The frequency of ACT is best individualised. As children/adolescents mature, techniques may need to be changed, and thus the ACT type and frequency is best reviewed at least biannually by physiotherapists with expertise in paediatric respiratory care. During acute exacerbations of bronchiectasis, children/adolescents should receive ACT more frequently.

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FIGURE 2

There are many different airway clearance techniques; in children/adolescents, these are age-specific and best taught by physiotherapists experienced in managing children/adolescents with bronchiectasis. GAD: gravity-assisted drainage; PEP: positive expiratory pressure.

Summary of evidence

We identified one small (n=24) RCT in children/adolescents [56] and two RCTs [57, 58] in adults (supplementary material). The paediatric study [56] that compared 1-month hospital-supervised, personalised ACT with unsupervised therapy at home (we equated this to controls without effective treatment) described a better median FEV₁ % pred in the intervention group (86.3%) versus controls (68.8%) at 1 month and 1 year (86.0% versus 69.3%). All three RCTs showed consistent improvement in lung function. For other critical outcomes, data were lacking in children/adolescents. Data from the adult-based RCTs [57, 58] (evidence table in the supplementary material) showed consistent results with improved QoL indices and sputum volume with ACT (versus no ACT), but no significant difference in the number of exacerbations (despite favouring ACT).

Additional evidence from adults (included here as mentioned in the methods and supplementary material): the benefits of ACT are supported by recent systematic reviews [23, 24, 59–61] of studies in adults (no available meta-analyses of data), but with very-low- to low-level evidence. One systematic review of acute exacerbations found six adult-based studies involving 120 people, but none included a “no treatment” group [61]. The authors reported ACT during acute exacerbations resulted in no adverse events, improved sputum clearance, and a non-statistically significant improvement in lung function and symptoms [61].

Other supportive evidence

Three recent CF-related systematic reviews [62–64] provided data supporting ACT, and one study [65] described significant declines in lung function (FEV₁ and forced vital capacity (FVC) % pred) without 3 weeks of ACT and improved lung function following its recommencement.

Justification of recommendation

Although the evidence for ACT improving clinical outcomes is very low, a strong recommendation was selected based on moderate desirable and trivial but time-consuming undesirable effects for undertaking ACT and the risk of harm if ACT is not undertaken. Where data exist, results are consistent and favour ACT compared with controls. Also, the panel and PAG described the use of ACT as a key intervention and one that is universally advocated for children/adolescents with bronchiectasis.

As there are many ACT methods, and developmental stage and cognitive abilities vary widely between children/adolescents (0–18 years), individualised therapy taught, and reviewed at least biannually, by paediatric-trained chest physiotherapists (figure 2) is recommended. Exacerbations increase airway secretions and enhancing their clearance would be beneficial.

Implementation considerations

Individualised ACT that are development- and age-appropriate are best taught by paediatric-trained chest physiotherapists (figure 2). Access to paediatric-trained physiotherapists was raised by the PAG. Adherence to the prescribed regime, especially over prolonged periods, is challenging. Also, the frequency and best ACT method(s) remain uncertain. Adjustment to the type of ACT during exacerbations may be necessary (e.g. exercises may not be feasible).

Recommendations

• In children/adolescents with bronchiectasis, we recommend that recombinant human DNase (rhDNase) is not used routinely. (Strong recommendation, very low quality of evidence.)

• In children/adolescents with bronchiectasis, we suggest that bromhexine is not used routinely. (Conditional recommendation, very low quality of evidence.)

• In children/adolescents with bronchiectasis, we suggest that neither inhaled mannitol nor hypertonic saline are used routinely. (Conditional recommendation, very low quality of evidence.)

Remarks: Inhaled mannitol or 6–7% hypertonic saline may be considered in selected patients, e.g. those with high daily symptoms, frequent exacerbations, difficulty in expectoration and/or poor QoL. If well tolerated, the use of hypertonic saline or mannitol could improve the QoL and facilitate expectoration. For hypertonic saline and mannitol, children should be old enough to tolerate these interventions, and the panel also considered that short-acting β₂-agonists should be used prior to inhaling either hypertonic saline or mannitol. The first dose of hypertonic saline or mannitol should be administered under medical supervision. The substantially higher cost of mannitol compared with hypertonic saline should also be taken into consideration.

Summary of evidence

We identified only adult-based RCTs involving rhDNase (n=2 [66, 67]), hypertonic saline (n=3 [68–70]), mannitol (n=2 [71, 72]) and bromhexine (n=1 [73]). Quality of evidence was very low to low, depending on the intervention

Regular rhDNase for 24 weeks (compared with placebo) significantly increased exacerbation rates (relative risk 1.35, 95% CI 1.01–1.79), and worsened FEV₁ and FVC [66]. Data from the smaller and shorter RCT [67] were consistent, but could not be combined with the larger study (supplementary material). rhDNase was also associated with increased hospitalisation and adverse events. Studies using mannitol failed to meet their primary end-point, but mannitol significantly improved some QoL subdomains and sputum volume, and prolonged time-to-next exacerbation. The effect of hypertonic saline was like mannitol; however, data from RCTs could not be combined. Although the small study on bromhexine favoured its use for sputum volume and FEV₁, there were more adverse events (OR 2.93, 95% CI 0.12–73.97). See the evidence table in the supplementary material.

Justification of recommendation

The panel considered that the overall weight of the literature, combined with biological plausibility, would lead most clinicians to be very concerned about using rhDNase due to the potential adverse effects. Although the quality of the evidence for rhDNase is very low, there is risk of substantial harm (increased risk of exacerbations and faster lung function decline). The panel also considered that the overall weight of the literature would lead most clinicians to be very concerned about using bromhexine due to the potential adverse effects. Thus, the balance of the evidence favours not using rhDNase and bromhexine routinely based on patient/parents values, the substantial adverse effects described above and the lack of efficacy of these treatments.

The balance probably favours administering hypertonic saline and mannitol in some patients. For example, in adults, mannitol (compared with controls) was beneficial (significantly fewer exacerbations, prolonged time-to-next exacerbation and symptomatic improvement) in the subgroup with a high symptom burden [74].

Implementation considerations

Health professionals should be warned of the potential harmful effects of rhDNase. For hypertonic saline and mannitol, children should be old enough to tolerate these interventions with pre-inhalation of a SABA. Education on using these medications and equipment care is also needed.

Recommendation

• In children/adolescents with bronchiectasis and an acute respiratory exacerbation, we recommend a systemic course of an appropriate antibiotic is used for 14 days. (Strong recommendation, moderate quality of evidence.)

Remarks: The empiric antibiotic of choice is amoxicillin-clavulanate, but the type of antibiotics chosen should be based on the patient's airway cultures (e.g. those with Pseudomonas aeruginosa require different treatment regimens to those without) and history of antibiotic hypersensitivity reactions. When the exacerbation is severe (e.g. the child/adolescent is hypoxic) and/or when the child/adolescent does not respond to oral antibiotics, intravenous antibiotics will be needed.

Summary of evidence

The evidence summary shows a single high-quality RCT supporting antibiotics for treating exacerbations. In that trial [45], amoxicillin-clavulanate was superior to placebo at resolving symptoms after 14 days treatment. Azithromycin was associated with improvement, but did not reach statistical significance of superiority over placebo. Amoxicillin-clavulanate also significantly reduced exacerbation duration, while this was similar between azithromycin and placebo among those whose symptoms resolved by day 14 [45]. No between-group differences were detected for time-to-next exacerbation, QoL or hospitalisations, although hospitalisation was uncommon in all groups [45]. The optimal duration of treatment with antibiotics is yet to be studied.

Other supportive evidence

Although no comparable placebo-controlled RCTs in adults exist, recommendations in adult guidelines [23, 24] are similar. Also, antibiotic treatment for acute exacerbations of bronchiectasis is considered standard of care.

Justification of recommendation

Our strong recommendation is based on a single high-quality RCT in children/adolescents and extensive clinical experience. Exacerbation resolution and duration both showed a benefit from the intervention. Importantly, the trial did not detect an increase in adverse events in the antibiotic treatment groups compared to placebo, although such events were uncommon.

An earlier RCT, which did not meet the inclusion criteria [46], comparing amoxicillin-clavulanate to azithromycin for treating non-severe exacerbations found that by day 21 azithromycin was non-inferior to amoxicillin-clavulanate (within 20% margin). However, symptom resolution in those receiving azithromycin took a median 4 days longer than those receiving amoxicillin-clavulanate, a statistical and clinically significant result [46].

Implementation considerations

Patients should have access to appropriate antibiotics for the recommended duration of treatment.

Recommendation

• In children/adolescents and adolescents with bronchiectasis and recurrent exacerbations, we recommend treatment with long-term macrolide antibiotics to reduce exacerbations. (Strong recommendation, low quality of evidence.)

Remarks: Based on the panel's experience, we suggest long-term macrolide antibiotics only in those who have had more than one hospitalised or three or more non-hospitalised exacerbations in the previous 12 months. Such a course should be for at least 6 months with regular reassessment to determine whether the antibiotic continues to provide a clinical benefit. Children/adolescents receiving longer treatment courses (>24 months) should continue to be evaluated for risk versus benefit. This suggestion is in the context of lacking data concerning when long-term azithromycin should be initiated, and the need for caution because of increasing antibiotic resistance among bacterial pathogens within patients and the community. While NTM are very rarely detected in children/adolescents with bronchiectasis, we suggest a lower airway specimen is obtained (when possible) to exclude their presence before commencing long-term macrolide antibiotics. We encourage strategies to ensure adherence to the macrolide regimen as ≥70% adherence improves efficacy and reduces antibiotic resistance.

Summary of evidence

There were three RCTs [17, 47, 48] and the combined data showed that macrolides reduced the number of children/adolescents experiencing any exacerbations during the trial period (relative risk 0.86, 95% CI 0.75–0.99). Of these RCTs, one involved only children/adolescents with HIV [48] and it was a small study that found no effect. The largest of the RCTs described that using long-term azithromycin halves the frequency of exacerbations (incidence rate ratio 0.50, 95% CI 0.35–0.70) and also likely reduces hospitalisation (p=0.06) [17].

There was no significant difference in serious adverse events when azithromycin was used compared to placebo. Indeed, serious adverse events were numerically lower in the azithromycin group (relative risk 0.57, 95% CI 0.31–1.05). However, there were significant increases in macrolide-resistant bacteria in the upper airways (nasopharyngeal swabs) in those receiving long-term azithromycin compared to placebo.

Other supportive evidence

Although the single high-quality study was undertaken in Indigenous children/adolescents, the efficacy of macrolides at reducing exacerbations is consistent. Meta-analysis examining the efficacy of macrolides in adults with bronchiectasis shows similar effects (relative risk of being exacerbation-free when taking azithromycin compared with placebo 1.66, 95% CI 1.37–2.02 in adults [75]). Studies in adults were substantially shorter in duration (6–12 months versus up to 24 months in the main paediatric RCT [17]). A recent RCT on azithromycin in adults with primary immunodeficiency and previous respiratory exacerbations (85% had bronchiectasis) also showed similar results (compared with placebo, hazard ratio (HR) for exacerbation 0.5, 95% CI 0.3–0.9; p=0.03; for hospitalisation HR 0.5, 95% CI 0.2–1.1; p=0.04; additional antibiotic required rate per patient-year 2.3, 95% CI 2.1–3.4, in the azithromycin group versus placebo 3.6, 95% CI 2.9–4.3; p=0.004) [76]. Following our final search date, a study involving children/adolescents and adults with primary ciliary dyskinesia found 6 months of azithromycin (versus placebo) significantly reduced exacerbation rates (rate ratio 0.45, 95% CI 0.26–0.78) [53], a similar effect size to this PICO's main contributing RCT [17].

Justification of recommendation

Although the overall quality of evidence was low, our strong recommendation is from the large effect on exacerbations, the panel's clinical experience, consistency of effect with adult-based RCTs and preventing exacerbations, being one of the key issues for the PAG. The importance and impact of exacerbations on children and families were crucial considerations for the strong recommendation. Also, there was relatively minimal possible harms of the intervention. Indeed, the sole study in the evidence table (supplementary material) with low risk of bias for all factors [17] reported (post hoc analyses) antibiotic use for non-pulmonary infections was significantly lower in the azithromycin group versus placebo (incidence rate ratio 0.50, 95% CI 0.31–0.81; p=0.005).

Implementation considerations

While an ECG is not necessary before commencing macrolides, a family history of prolonged QT syndrome, arrhythmias and acute cardiac events should be obtained and, when appropriate, an ECG ordered. Also, azithromycin should not be used in children/adolescents with contraindications to macrolides. This includes those with an abnormal ECG, liver function abnormality and azithromycin hypersensitivity.

Adherence ≥70% is important for efficacy [17] as well as reducing antibiotic resistance [77]. Adherence ≥70% (versus <70%) in the Australian azithromycin group was associated with lower carriage of any pathogen (OR 0.19, 95% CI 0.07–0.53) and fewer macrolide-resistant pathogens (OR 0.34, 95% CI 0.14–0.81) [77].

Recommendation

• In children/adolescents with bronchiectasis, we suggest eradication therapy following an initial or new detection of P. aeruginosa. (Conditional recommendation for the intervention, very low quality of evidence.)

Remarks: Evidence in bronchiectasis is indirect and limited to three small observational studies in adults focused on P. aeruginosa eradication. However, we suggest that eradication therapy should commence promptly after confirming P. aeruginosa is present (figure 3). Due to lack of evidence, we are unable to comment on eradication treatment for pathogens other than P. aeruginosa, which is informed on a case-by-case basis according to the clinical status of the child and the pathogen type. Antibiotic treatment should be made available in every setting where children/adolescents with bronchiectasis are managed.

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FIGURE 3

Suggested management approach used by the panel when Pseudomonas aeruginosa is first or newly isolated in a child with bronchiectasis. The suggested approach depends upon 1) the specimen type and 2) whether the child is symptomatic. However, panel members acknowledged the approach to initiating eradication treatment is controversial. Some physicians may still feel it is appropriate to initiate eradication therapy based only on a single upper airway specimen, even when symptoms and evidence of benefit in such circumstances are absent. ^#: if no lower airway specimen available, no treatment if asymptomatic; treat with intravenous anti-pseudomonal antibiotics for 2 weeks if symptomatic. ^¶: antibiotic choices are dependent upon patient factors (e.g. adherence, tolerance and preference), availability of antibiotics and P. aeruginosa susceptibility profile. ⁺: although there is no trial evidence, many paediatricians use a combination of two intravenous antibiotics. The recommendation for administering two antibiotics when employing short (2-week) intravenous antibiotic courses is made to align with the studies included in the systematic review and the European Respiratory Society adult guidelines [23].

Summary of evidence

There were no published studies in children/adolescents. Evidence was from three before-and-after trials in adults [78–80] who underwent eradication for P. aeruginosa. These indicate patients may experience improved QoL (compared to pre-eradication) and reduced exacerbation rates and hospitalisation. One study reported the mean number of antibiotic courses was 3.93 in the year before and 2.09 in the year post-eradication (p=0.002) [79]. Another study reported significant reductions in exacerbations, antibiotic use and hospitalisations (mean±sd total exacerbations 3.4±4.21 in the year before and 1.98±3.62 in the year during eradication using inhaled colistin; p<0.001). Corresponding values for hospitalisation and cycles of antibiotics were 1.94±2.8 and 1.18±1.73 (p=0.018), respectively [80]. The earlier study reported a non-significant reduction in the mean number of hospitalisations (0.39 pre-eradication and 0.29 post-eradication) [79]. However, before-and-after studies are subject to bias, including Hawthorne effects and regression to the mean.

In one study, 11 out of 28 patients who received eradication therapy were without P. aeruginosa at 15 months [78]; in another study, 13 out of 24 patients were also without this pathogen at a median 14.3 months [79]. The most recent study [80] reported that eight out of 35 (22.9%) patients who received 2 weeks of intravenous antibiotics and another five out of 50 (10%) patients who received 3 weeks of oral anti-pseudomonal treatment had eradicated P. aeruginosa. The 41 out of 67 (61.2%) who were then treated further with inhaled colistin were free of P. aeruginosa 3 months later and 40.3% were free at 12 months.

Other supportive evidence

Limited supportive data from a recent CF-related systematic review [81] found eradicating P. aeruginosa with nebulised antibiotics either alone or combined with oral antibiotics, compared to placebo or no treatment, can eradicate the organism for up to 2 years [81]. However, the impact on clinical outcomes is uncertain. A second CF review [82] on recent detection of methicillin-resistant Staphylococcus aureus in the lower airways reported short-term (28 days) eradication rates are better in those receiving targeted antibiotic treatment, but the effects are not sustained and clinical benefits uncertain.

Systematic reviews involving adults with bronchiectasis and chronic P. aeruginosa infection reported on eradication using inhaled antibiotics compared to placebo (OR 3.36, 95% CI 1.63–6.91; p=0.001) with significant reduction in exacerbation frequency (rate ratio 0.81, 95% CI 0.67–0.97; p=0.020) and proportion of patients with one or more exacerbations (OR 0.85, 95% CI 0.74–0.97; p=0.015) [83]. These data were consistent with another systematic review by different authors that focused on other treatment aspects [84].

Justification of recommendation

There is an established association between lower airway infection with pathogenic microorganisms and deteriorating clinical status and lung function in both the bronchiectasis [85] and CF [86, 87] literature. While there is currently no evidence for early eradication from well-conducted trials in children/adolescents with bronchiectasis, the panel suggests eradication treatment for P. aeruginosa. This recommendation places a higher value on the theoretical benefits of eradication and patient/carer values and preferences, and a lower value on possible treatment-related adverse effects.

Implementation considerations

Eradication therapy should employ a targeted antibiotic strategy for the minimum time necessary and measures should be instituted to support full adherence to the prescribed regimen. Like the adult ERS guideline [23], without clear evidence for one regimen over another, figure 3 illustrates commonly used approaches in children/adolescents by experts in the field.

Recommendation

• In children/adolescents with bronchiectasis, we suggest not using ICS with or without LABA routinely in either the short- or long-term, irrespective of stability or exacerbation. (Conditional recommendation, very low quality of evidence.)

Remarks: ICS maybe beneficial in those with eosinophilic airway inflammation. In the absence of any studies on the use with SABA in bronchiectasis, we cannot make any recommendation, but suggest an objective evaluation is undertaken if such asthma-type medications are considered. For some, SABA may be beneficial as pre-airway clearance therapies.

Summary of evidence

The evidence is based on five RCTs in adults (but not all contributed to all outcomes) and a single observational study in children/adolescents. The latter related to withdrawing ICS and had a high risk of bias, and the reported outcome measures were of doubtful clinical significance (FEV₁ and provocative concentration causing a 20% fall in FEV₁ (PC₂₀) changes were small) [88]. Overall, there is a lack of direct evidence for the use of ICS alone and in combination with LABA in children/adolescents with bronchiectasis. The studies are all very low quality, with only five RCTs in adults identified from systematic reviews [89, 90]. Four of the RCTs involved ICS versus placebo [91–94], while one examined ICS/LABA compared to ICS [95]. Where critical outcomes were obtained from these RCTs, the effect size for benefit was small and non-significant between groups.

For exacerbations, there was no difference between those who received versus those who did not receive ICS (studies ≤6 months: average number of participants mean difference −0.17, 95% CI −0.56–0.22; number of participants with at least one exacerbation OR 0.27, 95% CI 0.02–3.09, hospitalisation OR 0.20, 95% CI 0.02–1.90; studies >6 months: number of participants with improved frequency of exacerbation OR 1.61, 96% CI 0.68–3.81). See evidence table in the supplementary material for other outcomes.

RCT data in adults with bronchiectasis show increased adverse events when ICS are used and the risk increases with higher ICS doses. Also, there is observational study evidence of increased risk of NTM infection and pneumonia in adults with bronchiectasis and other chronic respiratory diseases who received ICS [96, 97].

Other supportive evidence

The panel considered that there is good evidence from the non-bronchiectasis literature that ICS can lead to adrenal suppression [98] and growth failure [99–101], as well as other adverse effects [97]. As there is no reason to suppose this would be different in bronchiectasis, these medications should not be used routinely unless there is objective evidence of benefit. Further, in adults with bronchiectasis, those commencing ICS had poorer outcomes than those starting macrolides (higher risk of hospitalised respiratory infection (HR 1.39, 95% CI 1.23–1.57) and exacerbations (HR 1.56, 95% CI 1.49–1.64)) [102].

Justification of recommendation

The evidence (albeit very low quality) shows a lack of efficacy for these medications. The panel considered the overall weight of the literature, examining the efficacy and safety of ICS in adults and in other conditions. This, combined with biological plausibility and the absence of any reason to suppose the effects are any different in children/adolescents, would lead most clinicians to be very concerned about potential adverse events from ICS, alone and in combination with LABA. Data on important adverse events are supported by systematic reviews in other chronic respiratory diseases. These potential serious adverse events (increased risk of NTM infection, pneumonia and tuberculosis), with strong biological plausibility for causation, suggest against routine use of ICS with or without LABA in either the short- or long-term. Also, there is supportive evidence of other possible harm as outlined above.

The fiscal cost associated with ICS prescription globally is substantial. Hence, prescribing ICS/LABA needs positive justification, which cannot be found in the current literature.

Implementation considerations

As bronchiectasis and eosinophilic asthma symptoms overlap, we recommend that if treatment with ICS or ICS/LABA is contemplated, every effort should be made to document acute bronchodilator sensitivity (acute spirometric response to SABA), atopy (skin prick tests and specific IgE) and airway eosinophilia (peripheral blood eosinophil count, sputum eosinophils and exhaled nitric oxide). It should be noted that the sensitivity and specificity of all these tests vary across the globe, but if there is no evidence of atopy or airway eosinophilia in a given patient, ICS and ICS/LABA are unlikely to have a role. If a blind trial of ICS or ICS/LABA is contemplated, because the above tests are equivocal or unavailable, objective evidence of benefit should be obtained if the medications are continued.

There is, however, a subgroup with asthma-type responses where using SABA pre-ACT may prove useful.

Usual practice statement

It is important to emphasise that surgery is rarely undertaken in the panel's experience, although we are aware that it is not uncommon in some settings. Surgery is only considered after maximal medical therapies (e.g. ACT, long-term antibiotics, etc.) have failed and the child/adolescent's QoL remains significantly impaired. When contemplated, a multidisciplinary approach is essential, and the decision should be based on the individual's clinical state and local surgical expertise.

Recommendation

• In children/adolescents with bronchiectasis, we recommend when considering surgery, factors to be taken into account include age, symptoms and disease burden, localisation of the bronchiectatic areas on chest CT scans, the underlying aetiology (influencing recurrence of disease), facility where surgery is undertaken (surgical expertise and availability of pre- and post-surgical care), and optimisation of the child's clinical state. (Strong recommendation, very low quality of evidence stemming from the narrative review.)

Remarks: The benefits from surgery are higher in those with localised disease where complete resection can be done and when the disease is not recurrent (i.e. absence of underlying aetiology such as immunodeficiency). Careful pre-operative evaluation as well as rehabilitation post-surgery improves outcome. Ideally, bronchoscopy and bronchoalveolar lavage are performed prior to surgery to exclude a foreign body and obtain microbiological samples. A ventilation/perfusion scan to delineate non-ventilated areas confirming the localised disease to plan for the surgery is likely beneficial. Optimisation of the child/adolescent's clinical state, including using appropriately targeted antibiotics, ACT and improving nutritional status, pre- and post-surgery is also necessary.

Summary of evidence

The narrative summary only identified observational studies. There was a single prospective [103] study and the rest (n=43) were retrospective. One meta-analysis [104] included the results of five paediatric studies. Also, 18 out of 42 (43%) studies were undertaken by surgical groups from one country, thus raising the possibility of selection and reporting bias. The limited evidence suggests better results if surgery is undertaken in specialised centres after a series of tests (ventilation/perfusion scan, bronchoscopy and chest CT scans) and optimising the patient's lung function pre-surgery. Factors to be considered include the underlying aetiology (influencing recurrence of disease), location and extent of disease (lobes affected).

Other supportive evidence

Surgery for bronchiectasis is now undertaken rarely in high-income countries, but is not uncommon in low- to middle-income countries. Members of the panel rarely advocate surgery to control bronchiectasis.

Justification of recommendation

Although evidence for assessing factors favouring lung surgery for children/adolescents with bronchiectasis is very low, the data from the studies are consistent and inform the current standard of care in specialist settings. Also, the panel and PAG expressed the view that standardised clinical care is very important when surgery is being considered, allowing risks versus benefits to be balanced.

Implementation considerations

Increasing accessibility to a multidisciplinary team with expertise in optimal pre-operative evaluation and careful patient selection is recommended. Video-assisted thoracoscopic surgery, compared to open thoracotomy, is associated with fewer complications and shorter post-operative hospital stay.

Recommendations

• In children/adolescents with bronchiectasis, we suggest that nutrition is optimised, including vitamin D status. (Conditional recommendation, very low quality of evidence stemming from the narrative review.)

Remark: There is no evidence upon which to recommend additional nutritional supplements.

• In children/adolescents with bronchiectasis, we suggest that exercise is encouraged on an ongoing basis; short periods of exercise training are unlikely to have a long-term effect. (Conditional recommendation, very low quality of evidence stemming from the narrative review.)

Remark: There is insufficient evidence to make a recommendation for establishing formal exercise and rehabilitation programmes.

• In children/adolescents with bronchiectasis, we suggest they are fully immunised according to their national immunisation programmes, including pneumococcal and annual seasonal influenza vaccines if these are not part of this programme. (Conditional recommendation, very low quality of evidence stemming from the narrative review.)

• In children/adolescents with bronchiectasis, we suggest they receive psychological support and education on equipment use and care. (Conditional recommendation, very low quality of evidence stemming from the narrative review.)

Summary of evidence

The evidence is overall of very low quality. The 14 included studies were: nine reviews, two RCTs [105, 106] in adults, one RCT in children/adolescents [107] and two observational studies [108, 109].

The desirable effects of routine immunisation, exercise and good nutrition are undeniable, but their magnitude is uncertain. Additional vaccinations for children/adolescents with bronchiectasis are likely beneficial, but the quality of the evidence is very low [107, 110]. The positive effects of psychological support and teaching appropriate equipment use and care for children/adolescents with chronic illness are also likely highly desirable, but there are no data on type, duration or intensity of support or how to assist with maintaining equipment. The data relevant for vitamin D were limited to adult-based studies [111].

Exercise training for short periods is unlikely to have prolonged effects and the implication is that exercise support must be ongoing. There is low quality of evidence supporting fewer pulmonary exacerbations and longer time-to-first exacerbation with exercise training. There are no agreed formal pulmonary rehabilitation programmes in children/adolescents and there are no data on what exercise interventions are most important. Whether a formal exercise programme is superior to encouragement of an active lifestyle is unclear.

Justification of recommendation

Recommendations are based upon placing a higher value on low/moderate quality of evidence for clinical improvement over a low value for concerns over uncertainty of magnitude and duration of benefit. The need for good nutrition, immunisation and exercise in childhood would be widely supported.

Implementation considerations

Increase the accessibility of children/adolescents to centres practising standard of care in low- and middle-income countries.

Recommendation

• In children/adolescents with bronchiectasis, we suggest that they and their family are counselled on cough and hand hygiene. Wherever possible, they should also avoid those with symptoms of viral respiratory infections. Children/adolescents managed within a CF clinic must follow their infection control policies. (Conditional recommendation, very low quality of evidence stemming from the narrative review.)

Addendum: The guideline was written pre-COVID-19, but in view of this, children/adolescents with bronchiectasis should follow measures recommended by local health authorities.