The independent contribution of Pseudomonas aeruginosa infection to long-term clinical outcomes in bronchiectasis

Discussion

This is the largest single study of bronchiectasis patients with the aim to assess the prevalence and burden of P. aeruginosa chronic infection.

While multiple studies have reported an association between P. aeruginosa and more severe bronchiectasis, and some have shown an association with poorer clinical outcomes, these were predominantly single centre, with small samples sizes and could not provide any information as to whether P. aeruginosa was a cause of poor outcomes or simply a marker of more severe disease. Our study contributes to this debate by clearly demonstrating that after adjustment for multiple possible confounding variables, P. aeruginosa remains associated with increased exacerbations, increased hospital admission risk and worse QoL. An association with mortality was only demonstrated in patients experiencing frequent exacerbations.

The prevalence of P. aeruginosa chronic infection in this study population was 15.0%, which is in keeping with the ranges of prior publications (9–31%) [12–17]. In a recent meta-analysis, Finch et al. identified a rate of P. aeruginosa colonisation of 24.1%, but the various studies included had different definitions of chronic colonisation, with some regarding a single isolate as indicative of chronic infection [11]. Mortality in this study population, with a follow-up of 5 years, was 10.8%, which is within the range of prior quoted studies over 4–5 years follow-up (Loebinger et al. [12] 9% at 4 years, Goeminne et al. [23] 20% at 5 years).

Several studies have identified P. aeruginosa chronic infection as a risk factor for mortality in bronchiectasis patients [11, 12, 21, 23, 24]. A pooled OR for mortality was 2.95 (95% CI 1.98–4.40; p<0.0001) in the Finch meta-analysis. In our cohort, for the univariate analysis we had a HR of 2.02 (95% CI 1.53–2.66; p<0.0001). Because this group of patients has more risk factors than other groups, such as poorer lung function, increased age, certain comorbidities, it is important to clearly assess if P. aeruginosa really has an independent impact factor on mortality. In that matter, a multivariate analysis was performed. Herein independent predictors of mortality were age, low BMI, number of exacerbations, but in isolation, persistent infection with P. aeruginosa was not.

To better understand why there was such a difference between univariate and multivariate analysis, the study population was divided into four groups (in terms of P. aeruginosa chronic infection and number of exacerbations) and a new multivariate analysis was performed. It became clear that having exacerbations plays a major role in mortality, independent of P. aeruginosa status. These data strengthen the importance of reducing exacerbations in all bronchiectasis patients, particularly in the case of P. aeruginosa chronic infection, where a higher mortality risk is seen with frequent exacerbations.

Even allowing for varying thresholds for admission across different healthcare systems, where home intravenous antibiotic may or may not be available, P. aeruginosa appears strongly correlated with exacerbation frequency and the risk of hospitalisation. The risk of hospital admission is related to severity of disease, number of exacerbations and the antibiotic susceptibility pattern of the pathogen responsible for the exacerbation, which in the case of P. aeruginosa is often limited to intravenous antibiotics.

QoL was evaluated in this study using the SGRQ, which has been extensively validated in bronchiectasis patients [25]. P. aeruginosa chronic infection has been associated with a lower QoL, and in the Finch et al. [11] meta-analysis there was an 18.2 points decrement in the SGRQ [21, 26]. The decrement justified by the presence of P. aeruginosa chronic infection was of 7.46 points (95% CI 2.93–12.00; p=0.001) which is considerably lower than the meta-analysis result. However, since it was adjusted for multiple variables, it gives us a better understanding of the real impact of this chronic infection in QoL, and it is still clearly clinically significant and far above the MCID for SGRQ.

If we accept now that there is robust evidence that P. aeruginosa drives worse outcomes in bronchiectasis there are a number of clinical implications. First, a limited amount of observational data suggest that it may be possible to prevent P. aeruginosa chronic infection by giving eradication treatment with oral, intravenous and/or inhaled antibiotics in combination [27]. A conditional recommendation in favour of this approach was provided in the 2017 ERS bronchiectasis guidelines [28]. Secondly, if P. aeruginosa infection cannot be prevented, then our data suggest that patients experiencing frequent exacerbations have the worst outcomes and so exacerbation prevention should be the key therapeutic focus. Long-term macrolides have been shown to reduce exacerbation frequency in bronchiectasis, but these studies included few subjects with P. aeruginosa [29]. Inhaled antibiotics such as colistin, aminoglycosides and aztreonam have been tested in large populations of patients with P. aeruginosa with equivocal results [28]. Larger studies are awaited. The ERS bronchiectasis guidelines provided a conditional recommendation for the use of inhaled antibiotics for patients with P. aeruginosa and three or more exacerbations per year, with macrolides to be added if inhaled antibiotics fail to control exacerbations [28]. Our results reinforce the importance of following these recommendations alongside optimising airway clearance, vaccination and the use of pulmonary rehabilitation in these patients [28].

The strengths of this study are the substantial number of patients included, the evaluation at different bronchiectasis clinical sites in different countries across Europe, and the considerable amount of patient data collected. A significant number of events, related to the large study population, enabled us to have a robust multivariate analysis with many variables, which helped to better understand the independent impact of P. aeruginosa chronic infection. Despite this, we acknowledge that the number of patients with P. aeruginosa not having frequent exacerbations was low. We cannot exclude the possibility that this group has an increased risk of death.

The main limitation of this study is not having a description of the cause of death in all cohorts. It would have been useful to know the number of deaths associated with respiratory causes. Another important limitation is that P. aeruginosa diagnosis is based on sputum culture, which is known to be insensitive, and the methods and frequency of sputum culture are not standardised [30]. This could potentially underestimate the frequency of P. aeruginosa chronic infection. Another limitation is the absence of an analysis of the impact that the P. aeruginosa phenotype/strain type and resistance pattern could have in terms of the patient's outcomes [30].

This study gives us a more accurate view of the real P. aeruginosa chronic infection prevalence across Europe. It also enables us to better understand its burden of disease, with a connection to poorer lung function, more exacerbations and hospitalisations, and a worse QoL. In terms of mortality, the relationship between P. aeruginosa and an increased risk of death, described previously in the literature, seems to be closely related with the fact that these patients have more exacerbations and more hospitalisations, rather than just the simple fact of being chronically infected by this pathogen. Our analysis cannot fully account for the “chicken or egg” question of which characteristic comes first in disease. It is not known whether patients with P. aeruginosa have more exacerbations and therefore have worse outcomes, or whether frequently exacerbating patients have a poor prognosis with frequent antibiotic courses leading to P. aeruginosa infection and poor outcomes. Our study can only demonstrate that the combination of these two parameters increases mortality. The mechanism by which exacerbations contribute to increase mortality in bronchiectasis is not fully understood and should be the subject of detailed translational research. Our work could have major implications for healthcare policy; it implies that adverse effects of P. aeruginosa may be mitigated by exacerbation prevention. Furthermore, it highlights the important impact of exacerbations in the non-Pseudomonas population, validating this as a key therapeutic target.