Comparative risks of chronic inhaled corticosteroids and macrolides for bronchiectasis

Discussion

In a Medicare population-based analysis, we found that chronic ICS use was associated with an increased risk of hospitalisation due to respiratory infection compared with macrolide monotherapy in patients with bronchiectasis. Despite a lower rate of prior infections in the ICS cohort compared with the macrolide cohort, e.g. baseline acute respiratory infection and history of Pseudomonas, and similar rates of baseline hospitalised respiratory infections compared with the macrolide cohort, after initiating ICSs patients had a higher relative risk of hospitalisation and death. The direction and magnitude of risk did not change in the subgroup of patients with an underlying COPD diagnosis.

The study cohort is typical of the older population (≥65 year old) in the USA, which includes ∼75% all bronchiectasis patients, in contrast to Europe where 50% of all bronchiectasis patients are ≥65 years old [30, 31]. The proportion of female patients in each treatment group (67% ICS and 73% macrolide) was higher than reported in the UK (58%), but similar to the overall population of adults with bronchiectasis in the USA (67%) [2, 30]. Treated patients included in our cohort were on average 1–2 years younger than the overall prevalent bronchiectasis population within Medicare, which is reasonable considering we included patients at “first new use” [32].

There is evidence that ICS therapy reduces exacerbations and slows the decline of quality of life in patients with advanced COPD [33]. To date, however, there is no evidence that long-term use of corticosteroids benefits patients with bronchiectasis and no large clinical trials have looked at ICS use in bronchiectasis. Several small randomised trials in patients with multiple exacerbations in the prior year have suggested an improvement in symptoms in patients receiving ICSs for 6–12 months, but no difference in other outcomes when compared with placebo [34–36]. The systematic review of therapies included in the 2010 British Thoracic Society guidelines and more recent 2017 European Respiratory Society guidelines concluded that there is a lack of evidence to support the chronic use of OCSs or ICSs in bronchiectasis [9, 11]. Despite these recommendations, the use of ICSs among such patients is common in the USA, even in patients without an indication for their use (asthma or COPD diagnoses) [14, 37–39]. Ongoing registry data and our finding that the risk of hospitalised respiratory infections was somewhat decreased in patients with bronchiectasis and an asthma diagnosis may reflect the benefit of appropriate use of ICSs to treat asthma.

There are data in other types of chronic lung disease suggesting that OCS or ICS use increases the risk of infection, particularly pneumonia [40], an outcome for which bronchiectasis patients are already at increased risk. In COPD patients, a population-based study identified a rate ratio of 1.69 (95% CI 1.63–1.75) for serious pneumonia in current ICS users [12]. We observed an attenuated but clinically meaningful 39% increase in the relative risk of hospitalised respiratory infection which was based on a comparison with another active treatment (macrolide monotherapy). A recent meta-analysis concluded that budesonide and fluticasone, with or without long-acting bronchodilators, are associated with increased risk of serious adverse pneumonia events in COPD patients, but not an increased risk of death [41]. We observed a similar pattern in our population of elderly bronchiectasis patients.

Antibiotics are used with the twin goals of reducing bacterial load in the airways, which in turn reduces airway inflammation, and, in the case of macrolides, exerting an immunomodulatory role independent of bacterial load reduction [15, 42]. Two small randomised clinical trials published in 2012 and 2013 evaluated long-term (6 months to 1 year) azithromycin and a third evaluated long-term erythromycin use in bronchiectasis patients [16–18]. While macrolide-treated groups experienced fewer respiratory exacerbations, defined as increasing symptoms (requiring treatment in two studies), there was limited or no improvement in overall lung function. Treatment guidelines have recommended that macrolides be considered for the subset of patients with a history of repeated exacerbations. For example, the 2017 European Respiratory Society guidelines suggest considering macrolides in patients with three or more exacerbations, either in the absence of P. aeruginosa infection or in those with P. aeruginosa infection in whom inhaled antibiotics are not efficacious or not tolerated [11]. In contrast to ICSs, we observed relatively low rates of chronic macrolide use in Medicare patients through 2014, similar to what was observed in the US Bronchiectasis and NTM Research Registry [39]. These rates may reflect the high rates of NTM isolation in the registry and may have increased after 2014 as time allows for practice change after the publication of the 2012/2013 randomised clinical trials.

Our results suggest that macrolides are associated with lower risks of common outcomes of treated acute infectious exacerbations and serious outcomes of hospitalised respiratory infection compared with ICSs. In general, the risks of antibiotic therapy compared with benefits are not clear. Azithromycin use has been linked to sudden cardiac death in population-based studies [43] and it is known to cause QT prolongation with potential for causing other cardiac arrhythmias, particularly when used with other drugs that also cause QT prolongation [44]. Furthermore, a significant risk of long-term azithromycin use could be the selection of macrolide-resistant NTM in patients with NTM isolated in respiratory specimens. Accordingly, macrolide monotherapy is not to be used in the treatment of pulmonary NTM disease (similar to tuberculosis where multiple drugs are used to diminish the evolution of drug resistance) [45]. The top 10 causes of hospitalisation or death within 30 days of discharge in our study population were similar between the two treatment cohorts, predominately related to respiratory failure and notably not cardiac arrest in either cohort.

Most therapies for bronchiectasis have received little research attention outside of CF populations, meaning the proposed benefits/risks of their use have been extrapolated from these and other settings of chronic lung disease such as COPD. However, the pathophysiology and natural history of bronchiectasis is distinct from CF-associated bronchiectasis and other lung diseases, and therapies that benefit one do not necessarily benefit the other. For example, DNase, which improves mucus clearance and outcomes in CF bronchiectasis patients, actually caused worsened lung function in other bronchiectasis patients [46, 47]. This underscores the importance of evaluating therapies within diverse populations of patients with bronchiectasis, rather than extrapolating from studies performed in other chronic lung disease conditions or bronchiectasis associated with CF.

Strengths of the study include the fact that it is a real-world, large population-based evaluation of the comparative risks of ICS therapy and macrolide monotherapy use in older bronchiectasis patients. Although older bronchiectasis patients tend to have more comorbidities, at least one study has shown that the aetiology and severity of bronchiectasis do not differ across age groups, except that the proportion of bronchiectasis due to COPD increased with age [31]. Our analysis used established new-user methodology, PS adjustment, an active control group and was limited to the first event of interest to account for channelling bias that otherwise limits our ability to determine causal association in observational studies. Although there were significant differences between the two exposure groups at treatment start, the proportion of COPD or Pseudomonas diagnoses was well balanced within each PS decile.

The main limitations result from the use of claims-based data, which limited our ability to confirm the bronchiectasis diagnosis and include disease symptoms or severity in our models and acute exacerbation definition. Although the PS balances the cohorts across known characteristics, there are likely additional (unmeasured) factors that influence treatment decisions. We were able to balance for important risk factors for hospitalisation and death of bronchiectasis patients, including acute respiratory infection history and comorbidities, in addition to utilisation history. There is the possibility of a small amount of residual confounding, given the slightly elevated risk in nonrespiratory infection hospitalisations, although that risk was predominantly driven by COPD exacerbations and other underlying lung disease. Furthermore, the Medicare study population consists of adults aged ≥65 years and results may not be applicable to younger bronchiectasis patients who have a different comorbidity profile [31]. There may be additional limitations extrapolating to other healthcare systems.

Our results provide evidence that the widespread use of chronic ICSs in older bronchiectasis patients without comorbid indications such as asthma and COPD is not supported. Future studies using registry or electronic health record data may be able to better group patients by comorbidities that impact therapy choice and include younger patients. Macrolides may be a better choice than ICSs to prevent hospitalised respiratory infections and acute respiratory infections in older bronchiectasis patients with frequent exacerbations. Further study of potential long-term risks and benefits of macrolide monotherapy is recommended.