Severe eosinophilic asthma: a roadmap to consensus

Towards a consensus on SEA

In November 2016, an expert task force of clinicians with an interest in and experience of SEA met to identify the key issues and to set out a roadmap for an independent evidence-based consensus statement intended to be of practical help to colleagues in the respiratory clinic. Figure 1 describes the development process for the meeting and this roadmap editorial.

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FIGURE 1

The biologics consensus roadmap

Diagnosis: what does a patient with SEA look like?

Early identification of patients with SEA in clinical practice is important; however, identifying these patients in day-to-day practice is not always straightforward [5, 16, 17]. A key initial step, as described by the European Respiratory Society (ERS)/American Thoracic Society (ATS) severe asthma guidelines, is to confirm the diagnosis of asthma and address comorbidities. Secondly, adherence to therapy and inhaler technique must be assessed before a diagnosis of severe uncontrolled asthma refractory to treatment can be confirmed [4]. This phenotype has been variously described in the literature and cluster analysis suggests a phenotype of patients with late-onset, eosinophilic, inflammation-predominant asthma [18].

Adult-onset asthma patients with a high blood eosinophil count (≥0.3×10⁹ per L) have been found to have a distinct phenotype of severe asthma with frequent exacerbations and poor prognosis [19]. Persistent airflow limitation and distal inflammation with air trapping are common in these patients, as is upper airway pathology such as chronic rhinosinusitis with nasal polyposis [17]. The characteristics described in these and other studies are not ubiquitous in all patients (some are found in almost all patients and some in a minority). As such, classification using a set of major and minor diagnostic criteria may help to identify this pattern (table 1).

Asthma patients with atopy will not necessarily have an allergic aetiology to their asthma [20]. Furthermore, it remains to be validated in atopic patients with blood eosinophilia, in the context of a thorough patient history, whether or not age at asthma onset, association between allergen exposure and asthma symptoms/exacerbations, and presence of fixed airflow obstruction and/or upper airway comorbidities can help to differentiate between severe allergic and severe eosinophilic asthma.

Biomarkers have been widely studied in SEA and, in clinical practice, blood eosinophil testing is readily available. There is a consistent relationship between blood and sputum eosinophilia [21]. Evidence exists that blood eosinophilia is a superior biomarker and that those patients with raised eosinophil counts have a higher frequency of severe exacerbation, poorer disease control and show a greater response to anti-eosinophilic therapies [10, 19, 22]. There is evidence to support the predictive value of eosinophils in response to these therapies, with a range of responses at different blood eosinophil levels, and patients with higher blood eosinophil levels (e.g. ≥300 cells·µL⁻¹) tending to have a better response to treatment [14, 22]. Overall, there remains a degree of debate about the optimal use and interpretation of biomarkers for SEA in clinical practice, and this revolves around two main concerns in particular. 1. The magnitude and persistence of eosinophilic disease (the level of eosinophilia which may indicate SEA in different patients, the number of test results needed to confirm SEA, and the management of the complications arising from oral corticosteroid use masking systemic eosinophilia and delaying diagnosis). 2. The role of other biomarkers such as exhaled nitric oxide fraction (F_eNO), serum periostin and dipeptidyl peptidase-4 (DPP-4).

A key aim is to develop a clinically useful aid to the identification and diagnosis of patients with severe asthma where eosinophils probably play an important role in the pathophysiology of disease. Based on a system of major and minor criteria to accurately phenotype these patients, each subject will need to meet a specific number or combination of criteria in order to reach a diagnosis of SEA. Robust validation of any tools will be required to ensure applicability.

Treatment: how do we treat patients with SEA?

Patients with severe asthma who have an eosinophilic-driven phenotype may benefit from newly developed precision medicines. One group clearly eligible for treatment with biologics is those patients with severe asthma adherent to high-dose inhaled corticosteroids who nevertheless have frequent exacerbations with or without symptoms, and who have persistently elevated levels of circulating blood eosinophils.

There are number of targeted therapies, both licensed and in development, that are appropriate for consideration in this patient population. Three biologic therapies are now licensed for severe asthma: omalizumab (anti-immunoglobulin E (IgE)), mepolizumab (anti-interleukin-5 (IL-5)) and reslizumab (anti-IL-5). Four more are currently in the development process: benralizumab (anti-IL-5Rα) has recently reported successful phase 3 results; tralokinumab (anti-IL-13) and dupilumab (anti-IL-4Rα) are in phase 3 trials; and pitrakinra (IL-4 and IL-13 antagonist) has completed phase 2 trials (all as of April 2017). Guidance is needed to understand how best to use these different treatments in practice, tailoring treatment choice to the clinical picture and selecting patients likely to benefit.

Anti-IgE therapy may reduce airway and blood eosinophils and result in less frequent exacerbations for patients with severe persistent allergic asthma. However, the drug is approved only for patients with severe allergic asthma due to perennial allergens and not all patients with uncontrolled asthma respond to anti-IgE therapy. It is not yet clear if persistent eosinophilic inflammation predicts a response to omalizumab, in particular in non-atopic asthma [5], and there is no real predictive factor available to manage this treatment [23]. However, methods such as basophil allergen threshold sensitivity may be effective at monitoring and evaluating response in different populations of patients taking omalizumab. This tool has been studied in patients with severe nut allergy to evaluate treatment efficacy, and has been explored as a biomarker in a small cohort of children with different manifestations of persistent allergic asthma [24, 25]. Interleukin-5 (IL-5) plays a critical role in eosinophil differentiation, maturation, recruitment, survival and activation in tissues. Anti-IL-5 therapies (such as mepolizumab, reslizumab and benralizumab) have all established efficacy in this patient population, have no serious safety concerns in clinical trials and have demonstrated favourable benefit–risk profiles [8–12, 15, 26]. In addition, IL-4 and IL-13 play a key role in the pathogenesis of asthma. Therapies that inhibit both IL-4 and IL-13 (including dupilumab) have shown some promising results [5].

All of these biologic treatments target the lower airways and associated symptoms but also have potential benefits in terms of comorbidities. These include potentially avoiding the adverse events associated with frequent oral steroid use, the rhinosinusitis and nasal polyps associated with upper airway eosinophilia, and atopic dermatitis associated with IL-4/IL-13 activity. Could the ultimate goal of anti-eosinophilic therapy be to minimise and perhaps even eliminate oral corticosteroid use, thereby consigning maintenance oral corticosteroids to history, at least in a majority of SEA patients?

There remains a need to look at how anti-eosinophilic therapies can be used to treat patients with uncontrolled disease, including children, adolescents and the elderly. In addition, patients with significant involvement of the upper airways, such as chronic rhinosinusitis with polyposis, will require a multidisciplinary team approach. Recommendations for other treatment options, including bronchial thermoplasty, macrolides and prostaglandin PGD₂-CRTH2 antagonists, also need to be evaluated.

Monitoring and follow-up

When patients are prescribed a biologic therapy for SEA, a number of questions are raised. Which sort of monitoring is necessary, how should patient follow-up be conducted, and how can we determine which patients have responded to treatment? Also, under which clinical circumstances should patients stop or switch therapy [26]?

Identifying therapeutic responders and non-responders is not easy, as it may take a year or more for a reduction in clinical exacerbations to emerge. Treatment goals vary and, most of the time, a combination of clinical signals is involved, including: symptom reduction (as captured by treatment effects on the individual asthma symptom load and the Asthma Control Test (ACT) or Asthma Control Questionnaire (ACQ)); reduced exacerbation rates; restoration of the sense of smell; and overall health-status restoration. This last point includes the ability to get a good night's sleep and feeling more alert (captured by Health-Related Quality of Life (HRQoL) questionnaires such as the Asthma Quality of Life Questionnaire). However, these asthma questionnaires do not always reflect this variety in treatment goals in clinical trials involving SEA.

A number of elements contribute to response and individual responses will differ. Monitoring of lung function, symptoms, quality-of-life and exacerbation history may support early clinical decisions on treatment response. Improvements in comorbidities, rather than in asthma itself, may result in higher quality-of-life scores and data should be collected from both the upper and lower airways to evaluate treatment effect. Thus, it is important to conduct a careful characterisation of the symptom profile in order to have objective measures to follow when response is evaluated. Anti-eosinophilic therapies for SEA are not curative, so guidance on the switching and stopping of these therapies, along with other systemic (e.g. oral corticosteroids) and inhaled treatments, is important. The initial suggestion of the expert task force is to develop a traffic-light system to determine response. Similar to the management approach for omalizumab, it has been agreed that patients with SEA require treatment for at least 4 months before an initial assessment of response can be determined. Following this, patients who are intermediate responders should either continue treatment for a year to assess response, or be considered for a switch to an alternative anti-eosinophilic therapy if response is low. The initial proposal, which will require further development, is described in figure 2.

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FIGURE 2

The traffic-light system for response and non-response following at least 4 months of treatment with an anti-eosinophilic therapy

Discussion and next steps

The high clinical need in severe asthma and the introduction of effective biological therapies for severe asthma related to eosinophilia make the development of a consensus to support clinicians treating these patients an important undertaking. The ERS has expressed an interest in taking this subject forward, potentially through an ERS research seminar and through discussion in sessions at national and international congresses. The intention is to develop a position statement supported by evidence to reflect a broader expert opinion around the management of patients with severe corticosteroid-refractory asthma, and to ensure that the fast-moving scientific developments in this field are applied to clinical practice for the benefit of patients.

Disclosures