Abstract
Eosinophilic granulomatosis with polyangiitis (EGPA), previously known as Churg–Strauss syndrome, is a multisystem disorder characterised by asthma, blood and tissue eosinophilia and small-vessel vasculitis. Eosinophilic tissue infiltration and extravascular granuloma formation can lead to damage in any organ, but it is classically seen to cause pulmonary infiltrates, sino-nasal disease, peripheral neuropathy, renal and cardiac involvement, and rashes.
EGPA is part of the anti-neutrophil cytoplasmic antibody (ANCA)-associated vasculitis syndromes, with the antibody being detected in ∼30–40% of cases and mostly against myeloperoxidase. Two genetically and clinically distinct phenotypes, defined by the presence or absence of ANCA have been identified. Treatment for EGPA focuses on inducing and maintaining disease remission. To date, oral corticosteroids remain first-line agents whilst second-line treatments include immunosuppressants such as cyclophosphamide, azathioprine, methotrexate, rituximab and mycophenolate mofetil. However, long-term steroid usage results in multiple and well-known adverse health effects and new insights into the pathophysiology of EGPA have allowed for the development of targeted biologic therapies, like the anti-eosinophilic, anti-interleukin-5 monoclonal antibodies.
Abstract
EGPA is a rare, multisystem disorder. Whilst effective, treatment with corticosteroids is associated with a high burden of side-effects. Deeper understanding of the pathophysiology is allowing for the development of novel therapeutic options. https://bit.ly/3Dv4nMa
Educational aims
To review and summarise EGPA and its aetiology.
To equip clinicians with a better understanding of clinical presentations to aid diagnosis.
To understand the developments in novel pharmacological therapies.
Case report
A 41-year-old female patient was referred to the severe asthma clinic with a diagnosis of Samter's triad (asthma, aspirin-exacerbated respiratory disease and rhinosinusitis) made 18 years ago. Despite treatment with and optimal adherence to high dose inhaled corticosteroids/long-acting β-agonist and long-acting muscarinic antagonist inhalers and montelukast, she had suffered from recurrent exacerbations needing three courses of oral corticosteroid therapy in the preceding 12 months.
At her first clinic review she had a peripheral blood eosinophil count of 0.9×109 cells per L, total IgE 55 kU·L−1 with specific IgE positive to house dust mite 22.5 kUA·L−1. She had a forced expiratory volume in 1 s (FEV1) of 2.56 L (84%) and evidence of airway inflammation based on the fraction of exhaled nitric oxide (FENO) of 122 ppb. On computer tomography (CT) images of the chest there was mild bronchial wall thickening, a CT of the sinuses showed mild to moderate mucosal thickening.
Given a recurrent need for prednisolone therapy, she commenced on the anti-interleukin-5 receptor biologic benralizumab 30 mg subcutaneously, to good effect. She remained exacerbation free with excellent symptom control for the following 11 months.
1 year after starting benralizumab, she contacted the centre. She reported loss of asthma control (breathlessness, wheeze and chest tightness) and worsening sino-nasal disease for the preceding month. She felt fatigued. She had noticed a widespread vasculitic rash over her arms and peripheral legs. Eosinophils were noted to be 0.15×109 cells per L for the first time since starting benralizumab. On assessment her oxygen saturations were 99%, FEV1 2.21 L (76%) and FENO 106 ppb. Troponin and renal function were normal as was the ECG. Her last benralizumab injection was 7 weeks ago.
The patient was treated with a course of oral prednisolone 40 mg per day for 5 days and asked to attend for a review on the day of her next benralizumab injection in a week's time or anytime sooner should her symptoms worsen.
On review 7 days later, the patient reported to feel only a little better; the rash had resolved. The blood eosinophil count was 3.08×109 cells per L pre-benralizumab injection, dropping to 0.1×109 cells per L 4 h after injection. Troponin and renal function were normal. Total IgE was 116 kU·L−1. Anti-neutrophil antibodies against proteinase-3 (PR3) and myeloperoxidase (MPO) were negative. A CT of the chest showed widespread severe bronchial wall thickening and areas of resolving dense consolidation with some ground-glass changes seen bilaterally. CT of the sinuses showed progression to severe sino-nasal mucosal thickening and polyposis including complete opacification of the intranasal olfactory recesses. A cardiovascular magnetic resonance scan was normal.
A further high-dose course of prednisolone was prescribed, which was tapered over the following weeks to continue on 5 mg daily; benralizumab was continued and the patient has remained well and exacerbation free over the course of the following months.
Introduction
Eosinophilic granulomatosis with polyangiitis (EGPA) is a rare multisystem disorder, which was first identified in 1951 by the pathologists Jacob Churg and Lotte Strauss [1]. Asthma, blood and tissue eosinophilia, and vasculitic inflammation defined a condition that has remained complex and heterogeneous [2, 3]. EGPA is part of the anti-neutrophil cytoplasmic antibody (ANCA)-associated vasculitis syndromes (AAV). It is one of the rarest AAV, with an incidence of 0.8–4 per million persons and a prevalence of around 8.1–22 per million persons [4]. Due to its low prevalence and limited epidemiological data, it remains challenging to diagnose and treat [5–7].
The mean age at diagnosis has been reported between 48 and 55 years [8–10]; however, patients have been diagnosed as young as 15 years of age [11, 12]. Through the advent of novel monoclonal antibodies targeting cytokines responsible for upregulation and proliferation of eosinophils, the clinical prognosis of patients has improved as has diagnostic accuracy [13–15].
Pathogenesis
The pathogenesis underpinning EGPA remains largely unknown; it is widely thought that different genetic and environmental factors come into play. Environmental factors including medications such as omalizumab and leukotriene receptor antagonists (LTRA), or irritants such a silica have been investigated as possible triggers. However, the evidence is weak [16] and in the case of omalizumab or LTRAs more likely the effect of steroid tapering rather than directly drug induced.
EGPA is a T-helper (Th)2 cell associated disease; Th2 cells mediate the activation and maintenance of humoral, or antibody-mediated, immune responses through the production of cytokines. Biopsy samples from affected tissues are rich in Th2 related markers such as CD294 [17] and eosinophilic selective chemokines and cytokines such as eotaxin-3, CCL17 and interleukin (IL)-4, IL-5 and IL-13, which induce the maturation and delayed apoptosis of eosinophils [18]. Hyper-eosinophilia is a cardinal feature of the condition. Organ damage can be caused directly by eosinophilic infiltration as seen in cardiac disease, or by the release of proinflammatory cytotoxic granule proteins such as major basic protein, eosinophilic cationic protein and eosinophil peroxidase [19]. The identification of these cytokines, especially IL-5, has allowed for novel biologic therapies to be developed in the first instance for severe eosinophilic asthma (SEA) and, more recently, for use in a broader range of hyper-eosinophilic conditions.
There is further evidence of Th17 involvement due to high levels of IL-17 later in the disease process [20]. Humoral immunity is also felt to play a role in the pathogenesis of EGPA. Elevation of IgE [21] and serum IgG4 is noted in EGPA; these are propagated by cytokines such as IL-4 and IL-5. The role of IgG4 in the pathogenesis remains unclear, the levels of IgG4 have not correlated with disease severity in current studies [22].
ANCA
ANCA are identified in ∼40% of patients [2]. Immunofluorescence assays show a perinuclear pattern of ANCA. In most cases of EGPA, ANCA is directed against MPO rather than PR3 [23]. Our knowledge about their pathogenic role in inflammation and organ damage is developing constantly.
A recent genome-wide association study has identified loci associated with the condition and has recognised two clinically and genetically distinct subgroups, shown in table 1. MPO ANCA+ was associated with HLA-DQ, whereas the ANCA− subset was associated with IL5/IRF1 and the barrier protein GPA33, both of which were not associated with MPO+ subsets [24].
These aren't completely distinct entities, with clinical findings overlapping in patients; cardiomyopathy and neuropathy can develop as a result of eosinophilic infiltration and vasculitis, so both processes are not mutually exclusive [24–26].
Clinical presentation
Clinical findings and course
Most patients experience a classic three phases pattern of symptoms and signs as shown in figure 1. EGPA may not necessarily manifest itself in such a defined order and distinct phases, with some patients only exhibiting some of these conditions. The mean time for the progression of patients from the initial prodromal allergic phase to the terminal vasculitic phase can take between 3 and 9 years [27].
Organ involvement
Respiratory
Asthma occurs in all cases of EGPA and tends to be severe with most patients becoming reliant on frequent courses or maintenance oral corticosteroids. A retrospective study looking at 157 patients reported that asthma preceded other systemic manifestations by a mean of 11.8 years and the severity of asthma increased 3–6 months before the onset of systemic disease. Patients were followed up for a mean of 7.4 years and 27% of patients went onto develop non-reversible obstructive symptoms [28]. Eosinophilic lung tissue infiltration was seen in 58% of patients including ground-glass changes, consolidation, pulmonary nodules and pleural effusions (figure 2d, e).
Sinus
Up to 75% of patients present with chronic rhinosinusitis. ∼55% of patients tend to have a background of nasal polyposis, with a past history of surgery or frequent use of oral corticosteroids [28].
Skin
Patients may present with palpable purpura or petechiae (especially of lower limbs); however, other lesions such as subcutaneous nodules can also occur (figure 2b) [26].
Cardiac
Cardiac manifestations range widely; they are caused both by eosinophilic infiltration and vasculitis. Cardiac disease is the primary cause of mortality in patients with EGPA. Coronary arteritis can lead to myocardial infarction and myocarditis, leading to fibrosis and thus restrictive cardiomyopathy. Untreated, this can lead to heart failure with associated morbidity and mortality. Other presentations include pericarditis, arrhythmias and pericardial effusions. Troponin at baseline and during flares is a useful and easily available blood marker. ECG and echocardiography are recommended for all patients. Cardiac magnetic resonance imaging (MRI) is the most sensitive diagnostic technique and a valuable tool to detect cardiac involvement early (figure 2c) [29, 30].
Gastrointestinal
Eosinophilic infiltration in the gastrointestinal tract leads to abdominal pain, diarrhoea and nausea. This may present before or in conjunction with the vasculitis phase. Patients present with mucosal ulceration especially affecting the duodenum, rectal bleeding and ischaemic bowel. Emergency presentations can also occur such as bowel obstructions and perforation necessitating surgery [31].
Peripheral neuropathy
Peripheral neuropathy can present in 75–80% of patients, with central nervous system involvement in 10–39%. Patients present initially with sensory impairment, followed by motor deficits. The most common presentation is mononeuritis multiplex, with axonal derangement, which leads to paraesthesia and pain. The most common areas tend to be the dermatomes supplied by the common peroneal nerves and tibial nerves. In the upper limb the tibial, ulnar and median nerves are usually affected. Nerve conduction studies can aid with the diagnosis of patients [32].
Renal
Renal involvement occurs in ∼25% patients and the most common presentation is with necrotising crescentic glomerulonephritis. This is commonly found in ANCA positive cases. Clinical features can vary from isolated proteinuria, isolated haematuria to rapidly progressive glomerulonephritis [26]. Although it was initially thought that renal involvement in EGPA was benign; increasingly, studies have reported that nearly 20% of patients can develop end-stage renal disease in 4 years from first presentation, warranting regular monitoring and early management of renal disease [33, 34].
Clinical outcomes
The five-factor score (FFS), created by the French Vasculitis Study Group, can be used at diagnosis to assess the severity of EGPA and to predict prognosis. Initially proposed in 1996, it underwent revision in 2009 and assigns scores depending on organ involvement, clinical and biological parameters. One point each is attributed to older age (>65 years), renal insufficiency, cardiac insufficiency and significant gastrointestinal involvement, as well as for the absence of ENT (ear, nose and throat) manifestations.
It has been reported that survival rate is improved when stratifying treatment according to the FFS and that the FFS score at diagnosis can help to predict the chance of relapse [35–37]. 2009 FFS values of 0, 1, and 2 are associated with respective 5-year mortality rates of 9%, 21%, and 40%; [37]. Factors which influence the frequency of relapse have noted to be lower eosinophil count at baseline and MPO-positivity [25, 26, 35].
A study looking at 50 patients reported that higher doses of steroids were needed to maintain remission in ANCA positive patients [38]. This was supported by another study which observed more frequent relapses in patients with MPO targeted ANCA [35]. Low-dose, long-term corticosteroid treatment seems to reduce relapse risk; however, this needs to be balanced against corticosteroid-related side-effects [34].
The most commonly reported sequelae in the disease are asthma and neurological symptoms [35]. Cardiac manifestations in the form of myocardial infarction, myocarditis and coronary arteritis have been demonstrated to affect survival [26], as did age of onset ≥65 years [39]. Biologic therapies are expected to affect survival and relapse rates positively in the future.
Classification of EGPA
ANCA-associated vasculitides pose as a diagnostic challenge for many clinicians. Various diagnostic and classification criteria have been published. The 1984 Lanham criteria, the American College of Rheumatology classification criteria, the 2012 revised Chapel Hill Consensus conference and the EGPA consensus task force have helped to define and identify patients for clinical trials [5, 40–42].
The 2022 American College of Rheumatology/European Alliance of Associations classification criteria is a newly validated tool used to assist in diagnosing EGPA (table 2) [41]. It is applied to patients who have a confirmed diagnosis of a small- or medium-vessel vasculitis. It allocates different scores to different sub-criteria; a score ≥6 is needed for a diagnosis of EGPA.
This criterion was altered as previous versions led to frequent overlaps between different AAV. The criteria were validated with a group of 119 EGPA cases and 437 comparators; the sensitivity was found to be 85% (95% CI 77–91%) and specificity 99% (95% CI 98–100%) [41].
The European Respiratory Society formed the EGPA consenus task force which made 22 recommendations for the diagnosis and management of EGPA (table 3) [5]. This involved guidance around the diagnostic criteria for the condition. These criteria encompass the varying nature of patients’ presentations, whilst also setting the requirement of having clinical and serological proof of EGPA.
Relationship between SEA and EGPA
Respiratory manifestations, especially in the form of asthma, tend to present several years prior to diagnosis of EGPA [28]. SEA is considered to be a prodromal phase of EGPA for some patients (see the case report). With initial respiratory tract symptoms affecting the upper and lower airways, patients then develop organ involvement due to eosinophilic tissue infiltration and vasculitis [43]. Due to the similarity in the pathogenesis of the two conditions, driven by hyper-eosinophilia, similar treatments have been and continue to be trialled and tested. This includes anti-IL-5 biological agents, which have acted as corticosteroid-sparing treatments in both SEA [44, 45] and EGPA [13, 46].
Diagnostic work-up
There are currently no reliable biomarkers that can be used to identify and diagnose EGPA [47]; however, a comprehensive work-up of patients is essential to affirm diagnosis and set out treatment plans. This includes IgE titre levels, IgG and subsets, rheumatoid factor, C-reactive protein, erythrocyte sedimentation rate, antinuclear antibodies (ANCA), troponin, renal function, tryptase and vitamin B12. Stool and serology sampling for parasites ought to be considered depending on the clinical and travel history, as should a thorough drug and toxin review [7]. Organ specific testing should be utilised when appropriate. To assess pulmonary health, functional testing alongside radiological tests such as CT scans and chest radiographs are to be used. Echocardiogram or preferentially cardiac MRIs should be used to rule out involvement. Urinalysis should be sued to assess for haematuria and bone marrow biopsy to rule out haematological causes for eosinophilia [3, 5, 40].
Biopsy of affected organ systems can aid in diagnosing EGPA and monitoring relapses. Biopsies may illustrate eosinophilic infiltrates, small-to-medium sized vessel vasculitis and extravascular granulomas. The vasculitis consists of fibroid necrosis of the vasculature wall and can be associated with eosinophilic infiltrates and palisading granulomas [6, 41]. An in-depth assessment will help to evaluate inflammatory activity and differentiate the disease from other hyper-eosinophilic conditions.
Differential diagnoses
Vasculitic and eosinophilic disorders primarily form the differential diagnoses for EGPA. Other small vessel AAVs, such as granulomatosis with polyangiitis and microscopic polyangiitis, may present with similar clinical features to EGPA. However, the latter is characterised by elevated blood and tissue eosinophils and the presence of asthma [40], whilst the others are not.
Chronic eosinophilic pneumonia (CEP) commonly presents with symptoms of breathlessness, cough, fatigue and low-grade fever as well as pulmonary infiltrates and hyper-eosinophilia and it can as such be difficult to distinguish from EGPA, especially EGPA in its early phase. Asthma can precede or accompany CEP in up to 50% of cases. However, EGPA is a vasculitic multisystem disease whereas CEP is not [48].
Non-myeloid neoplasms, including Hodgkin Lymphoma, T-cell neoplasms and some solid tumours, may be associated with hyper-eosinophilia and should be excluded [49].
Hyper-eosinophilic syndrome (HES) comprises of serum hyper-eosinophilia and tissue eosinophilic infiltration. This leads to organ damage and dysfunction [50, 51]. Clinically, both HES and EGPA can present with similar symptoms due to the organs affected. Patients present with sino-nasal disease and eosinophilic pneumonia; however, in HES patients do not frequently present with asthma [52]. HES are heterogeneous with idiopathic or overlap syndromes most commonly presenting with pulmonary infiltrations; myeloid HES sees clonal eosinophilic involvement, such as FIP1L1/PDGFRA; in lymphoid-variant HES there is a clonal or phenotypically aberrant lymphoid population [50, 51].
Management
Scoring tools
There are currently no specific assessment and monitoring tools that exist for EGPA. General vasculitis assessment tools such as the Birmingham Vasculitis Activity Score (BVAS) and asthma-specific tools such as the Asthma Control Questionnaire (ACQ) can be utilised. These can be used alongside clinical presentation and biochemistry to assess for severity of disease and monitor for flares. The BVAS tool looks at 56 organ-based symptoms and scores these depending on if they are new or worsening in the past 4 weeks [53]. It is not specific for EGPA and is more commonly used in other AAV. The ACQ focuses on the past 1 week and has seven items which patients respond to, including spirometry results. This, alongside other biomarkers allows for treatment to be started or escalated as needed [54]. A recent retrospective study looked at 119 patients with EGPA and compared accuracy of using the FFS and BVAS in assessing survival and concluded that the 2009 FFS had the best prognostic accuracy for survival [36].
Treatment: induction regimes
Corticosteroids
Due to the rarity of the condition, there is a paucity of randomised controlled trials looking at gold-standard remission induction and remission treatments for patients.
In patients without poor prognostic factors, i.e. FFS score of 0, or limited disease corticosteroids alone are used to achieve remission. Corticosteroids can be given intravenously (usually methylprednisolone 500–1000 mg for 1–3 days in more severe cases) or orally 1 mg·kg−1·day−1[55]. Due to the well-documented side-effects of corticosteroids, the dose ought to be tapered to the lowest dose possible. In patients experiencing disease relapse when the dose is tapered down [12], steroid-sparing agents, such as immunosuppressants, or anti-IL-5 biologics are used to maintain remission.
Immunosuppressants
Patients with an FFS score of 0 are found to enter remission with just corticosteroids; however, patients with FFS ≥1 have a worse prognosis and are usually treated with glucocorticoid and immunosuppressants.
Cyclophosphamide
Cyclophosphamide has traditionally been used to induce remission whilst azathioprine, methotrexate and mycophenolate mofetil (MMF) are used to maintain remission alongside oral corticosteroids.
Cyclophosphamide has successfully been used to induce remission in a randomised controlled trial comparing six and 12 cyclophosphamide pulses given with corticosteroids to 67 patients. Both groups achieved remission and were equally effective; however, relapses were more common in the six pulses group [35]. In granulomatosis with polyangiitis and microscopic polyangiitis vasculitides, cyclophosphamide was equally effective when given as continuous oral therapy versus intravenous pulses with a lower risk of adverse effects in the intravenous group. Side-effects of cyclophosphamide include bone marrow suppression and increased risk of cancer, as well as ovarian failure and sperm abnormalities [56].
The usefulness of other immunosuppressants for EGPA lacks prospective, EGPA-focussed trial data and their effectiveness remains controversial. A randomised controlled trial (CHUSPAN2) which looked at different non-severe AAV including EGPA, concluded that azathioprine was not superior to placebo in preventing relapse, inducing remission or reducing exacerbation rate of asthma when administered for 12 months [57]. A retrospective study of 188 Japanese patients with EGPA suggested that over a median follow-up period of 56 months, azathioprine may be an independent factor for lower relapse rates [25]. Azathioprine has been compared to other treatments and in patients with AAV it was found to be equally effective as methotrexate but with lower efficacy when compared with rituximab [58, 59].
In a prospective trial of 28 patents with EGPA, methotrexate, when given alongside prednisolone, achieved remission in 72% but relapse occurred in 50% within 1 year [60]. A small observational study of 15 patients with newly diagnosed EGPA reported remission in 67% of patients who received MMF together with prednisolone at 12 months [61]. However, MMF was found to be less effective than azathioprine in non-EGPA AAVs when used for remission maintenance [62]. Similarly, in patients with relapsing and refractory EGPA, MMF was found to be less effective than rituximab [63]. Immunosuppressants require regular blood and lung function testing to monitor for organ toxicity.
Rituximab
Rituximab is an anti-CD20 chimeric mouse-human monoclonal IgG antibody that induces B-cell depletion. Case series and cohort studies report success rates in inducing remission in up to 80% of patients although lower rates are reported in ANCA negative patients [64, 65].
The REOVAS trial, a double-blind controlled trial of rituximab in EGPA randomised patients with an FFS score of 0 into rituximab+corticosteroids versus corticosteroids and patients with FFS score of ≥1 to rituximab+corticosteroids versus cyclophosphamide+corticosteroids. Rituximab was not found to be superior in either subgroup. Results of a trial looking at rituximab versus azathioprine as maintenance of remission are expected in due course (MAINRITSEG study; ClinicalTrials.gov identifier: NCT03164473). Earlier studies are presented in table 4.
Treatment: anti-eosinophilic biologic therapies
Monoclonal antibodies, including therapies which specifically target eosinophils through suppressing Th2 inflammation, have been trialled and proven effective in SEA, HES and more recently, EGPA. They have proven most successful in airways dominant EGPA with effective steroid-sparing activity. The results of recent studies are summarised in the table 4.
IL-5 plays a vital role in the proliferation and differentiation of eosinophils and in preventing apoptosis. Monoclonal antibodies against IL-5 or the IL-5 receptor (anti-IL5/5R) have proven effective in disease control and steroid-sparing activity in asthma [72]. In EGPA, so far only mepolizumab has been tested in a randomised controlled trial [13], whereas the effect of benralizumab and reslizumab has been reported in small observational studies (table 4). A multicentre active controlled phase 3 study comparing the efficacy and safety of benralizumab versus mepolizumab in patients with relapsing or refractory EGPA is currently ongoing (MANDARA study; ClinicalTrials.gov identifier: NCT04157348), as are trials with reslizumab and benralizumab.
Biologics may be a means through which complete remission can be achieved with reduced exposure to corticosteroids for patients. However, larger randomised controlled trials with longer follow-up periods are required to better understand the optimal use of these medications.
Conclusion
EGPA remains a rare but complex and heterogeneous multisystem disease. In the future, outcomes may improve through early diagnosis, updates in classification criteria and the use of novel biologic agents. Corticosteroids remain effective in inducing remission and maintenance of it, but their long-term side-effects can be deleterious. The dichotomy between ANCA positive versus ANCA negative EGPA shapes clinical presentation, diagnosis, monitoring and, importantly, treatments and outcomes. A deeper understanding of the pathophysiology of EGPA and its subgroups will support the development of effective, safe and personalised treatments.
Key points
Respiratory manifestations, in the form of asthma and sino-nasal disease, tend to precede other clinical presentations in patients by several years.
No reliable biomarkers have been identified for the identification and diagnosis of EGPA; however, a thorough work-up using different laboratory and radiological techniques should be carried out in a patient suspected of having the condition.
Monoclonal antibodies targeting IL-5 have proven effective in small cohort studies for disease remission and as steroid-sparing agents, with larger randomised controlled trials being undertaken currently.
Self-evaluation questions
According to a genome-wide association study, which genetic associations were identified with the MPO ANCA positive subgroup?
GPA33 and IL5/IRF1
HLA-DQA1 and IL5/IRF1
HLA-DQA1 and HLA-DRB1
HLA-DRB1 and GPA33
Which scoring tool can be utilised to assess severity and estimate prognosis at diagnosis?
Birmingham Vasculitis Activity Score
Five-factor score
Asthma Quality of Life Questionnaire
Asthma Control Questionnaire
Which class of biologic agents does benralizumab belong to?
Anti-CD20
Anti-IgE
Anti-IL-5R
Anti-IL-4
Involvement of which organ system is the primary cause of mortality in patients with EGPA?
Cardiac
Respiratory
Gastrointestinal
Renal
Suggested answers
1. c.
2. b.
3. c.
4. a.
Footnotes
Conflict of interest: V. Alam has nothing to disclose.
Conflict of interest: A.M. Nanzer has received speaker's fees and conference support from AstraZeneca, Chiesi, Teva and Napp, outside the submitted work.
- Received July 21, 2022.
- Accepted October 25, 2022.
- Copyright ©ERS 2022
Breathe articles are open access and distributed under the terms of the Creative Commons Attribution Non-Commercial Licence 4.0.