How can we minimise the use of regular oral corticosteroids in asthma?

The burden of OCS is the key to all definitions of severe asthma

Whereas multiple definitions of severe asthma have been proposed in adults and children, none of them is considered to be self-sufficient for the development of new drugs [5, 24–27]. It actually seems that the only convergence between academic definitions and inclusion criteria in randomised controlled trials is the burden of treatment assessed through levels of exposure to β-2 agonists and, most importantly, to ICSs and systemic corticosteroids. Beyond uncontrolled symptoms and variable airflow obstruction, the use of systemic or OCSs for >50% of the year is the given threshold for severity in most academic definitions. Repeated OCS burst or daily OCSs despite high-dose treatment, including ICSs, are the main criteria for defining severe asthma in children. Epidemiological data showed that a significant increase in the risk of severe side-effects could appear at levels as low as 0.5 g·year⁻¹ and became highly significant at levels >1 g·year⁻¹ [15, 28–31]. Most randomised controlled trials used much lower thresholds, usually set at two episodes per year requiring OCS use for ≥2 days. In OCS-sparing trials, continuous use of OCSs at a daily dose of at least 5 mg for ≥6 months was considered [32–34]. Interestingly, these trials were designed very similarly and were based on primary outcomes nearly identical to those developed for registration studies with ICSs in the 1970s [3]. Surprisingly, in France as in other countries, OCS use is still increasing [12, 17]. Chronic airway diseases are by far the most common reason for using OCSs in the short, middle and long term [35].

Building on these shared views, a simple clinical workflow has been developed and promoted as a guidance for managing difficult-to-treat patients [5, 36]. Although unspecific and encompassing many different situations, the word “difficult” mostly refers to frequent use of OCSs [37]. Ruling out alternative diagnoses and interfering comorbidities represent the two main pillars of this workflow. The third pillar, poor adherence, still challenges both patients and physicians. As poor adherence to ICSs is known to increase the risk for more frequent bursts of OCSs, it is highly likely that the burden in terms of side-effects in this population would be at least the same. In children, mechanisms of resistance to ICSs may be different according to age, with a large part of preschool severe asthma not related to allergy and/or eosinophilia [38–40]. Furthermore, severity may be related to lung function alteration, with a fixed airway obstruction or a progressive decline in forced expiratory volume in 1 s (FEV₁), despite ICS daily treatment [41].

Poor corticosteroid response

The heterogeneity of asthma is inherent to its definition which is based first on airway hyperresponsiveness and secondly on an undefined chronic inflammation. Building a step-by-step classification of severity based on ICS requirements to achieve control implies that the disease is steroid-sensitive in a dose–dependent manner and becomes severe when ICSs alone fail to obtain control despite being used at their highest dosage. Whether this should be referred to as a “resistant”, “insensitive”, “poorly sensitive” or a “refractory” disease is a literal debate potentially misleading for non-native speakers of English. Resistant or refractory means that the disease will not benefit from corticosteroids irrespective of dose or route of administration, which is extremely paradoxical considering the OCS-based definitions of severe asthma. The ICS step-up strategy proposed through the Global Initiative for Asthma steps 2–5 in its former versions is supported by large trials such as GOAL (Gaining Optimal Asthma Control) [42], where the incremental benefit of the highest doses appeared limited. Now the Global Initiative for Asthma step-up plan (which is mostly based on existing evidence) proposes an approach based on the targeting of multiple pathways (long-acting β-agonists, long-acting muscarinic receptor antagonists, leukotriene receptor antagonists and specific immunotherapy, for example) rather than fostering the increasing dose of ICSs [43]. Maintenance and reliever therapies based on ICS–long-acting β-agonists as needed were shown to be superior to regular therapies with short-acting β-agonists on demand in reducing exacerbation rates, and this is also suggestive of a certain level of ICS dose-dependency of the underlying airway inflammation. ICSs were developed as OCS-sparing agents [3] and it is likely that some of these effects are driven by their systemic passage, given their ability to induce hypothalamic–pituitary–adrenal (HPA) axis slowing and other systemic related adverse events, such as skin bruising for instance [44].

Intuitively, the efficacy of OCSs in situations where ICSs have failed can relate to several situations: 1) ICSs are unable to reach their target because of inappropriate handling and/or an unreachable target (e.g. distal inflammation including the bone marrow and/or mucus plugging, and upper airway inflammation such as chronic rhinosinusitis with nasal polyps; 2) the target is reached but insufficiently silenced by ICSs due to molecular interferences; 3) the systemic part of the disease is playing a greater role than expected (e.g. when OCS-dependent asthma is the apparent feature of otherwise occult eosinophilic granulomatosis with polyangiitis (EGPA)); 4) patients have an inflammatory drive that is intrinsically relatively corticosteroid unresponsive; 5) the patients have a lesser response to ICSs than the average subject; and 6) subjects benefit from nonrespiratory effects (e.g. central nervous system effects such as pain relief or excitation) of OCSs [45, 46]. The OCS-sparing effects of anti-interleukin (IL)-5, anti-IL-5R and anti-IL-4R do not always enable complete weaning. Aside from supplementation of a potential adrenal insufficiency, the positive benefits of OCSs over ICSs may go beyond T2 suppression via additional mechanisms (e.g. nongenomic effects) in these patients. Accordingly, a more accurate understanding of the biological effects of corticosteroids is required.

Biological evidence and mechanism of action

The mechanism of action of steroids is actually not perfectly known [47, 48]. This is quite surprising in view of their frequent use in the general population along with a relative perception of efficacy and safety.

Glucocorticoids (GCs) bind to the glucocorticoid receptor (GR) and the complex GC–GR will be translocated into the cell nucleus with the help of one member of the importin family [49]. The GC–GR complex will then bind to specific DNA structures and induce or repress target gene expression. Nongenomic effects of corticosteroids are related to direct interaction with other proteins, including transcription factors [7].

Based on the clinical response to a burst of corticosteroids (usually defined as the ability to improve FEV₁ by 10–15%) [50–52], multiple in vitro and/or ex vivo assays deciphered several biological scenarios, underlying impaired corticosteroid sensitivity, such as reduced or impaired GR expression or binding, maladapted importin7–GR interaction that can lead to decreased nuclear translocation and, more classically, reduced glucocorticoid responsive element accessibility as a consequence of histone acetyltransferases/histone deacetylases imbalance [53–56]. Among histone deacetylases down-regulators, cigarette smoking, obesity and microbial pathogens look highly relevant in the context of poor steroid sensitivity.

Other factors, such as poor absorption affecting prednisone bioavailability [57] or poor treatment adherence, may also be investigated in the context of poor steroid efficiency.

Appropriate understanding of steroid responsiveness fundamentally requires clear objective criteria, reflecting responses to these agents. This would allow for a more accurate assessment of the underlying biological processes involved. However, it is unlikely that the biological mechanisms associated with changes in lung function after a burst of systemic steroids would be exactly similar to those involved in the prevention of recurrence of exacerbations.

Finally, various models and different samples from humans showed that T2 inflammation and steroid responsiveness grossly go along each other [9, 58, 59]. IL-4 and IL-5 seem to be major steroid targets. In contrast, inflammatory pathways considered to be outside the borders of T2 mechanisms (e.g. T-helper cell (T_H)1 and T_H17 [60], and their associated pathways of Toll-like receptor, NOD, phosphatase and tensin homolog and phosphoinositide 3-kinases) have been associated with poor steroid response [61–67]. Bronchial smooth muscle cells are also poorly sensitive to corticosteroids, but this is not specific to severe asthma. Indeed, although the expressions of both C-EBPα and GR were reduced in the bronchial smooth muscle of both severe and nonsevere asthmatics, there is an impaired nuclear translocation of the GR following dexamethasone, only in severe asthmatic patients [68–72]. Similarly, fibrocytes obtained from patients with severe asthmatic appear insensitive to dexamethasone compared to those obtained from nonsevere patients with asthma or healthy controls [73, 74]. In a study of childhood difficult asthma, only 11% of 102 patients were shown to be completely corticosteroid unresponsive to a single intramuscular injection of triamcinolone, indicating that 89% of the patients had some degree of corticosteroid responsiveness [75].

In the U-BIOPRED cohort, some patients treated with systemic steroids did not have a high expression of the GR signature. It was also shown that infection-induced impairment of GR translocation to the nucleus was mostly driven by the JAK–STAT pathway [65].

Alarmins such as IL-33, thymic stromal lymphopoietin and IL-25 [76–80] are poorly steroid sensitive and targeting monoclonal antibodies is currently under development in the field of severe asthma. Whether they will modulate most of the pathways targeted by corticosteroids is also an extremely relevant question to anticipate in ICS-sensitive mild-to-moderate asthma. The alarmins pathway may be particularly relevant in children, especially in those with severe asthma prone to frequent exacerbations mainly triggered by viruses (rhinoviruses), which induce alarmins secretion by bronchial epithelial cells [81, 82].

Clinical and physiological evidence

A burst of steroids induces numerous changes in symptoms, exacerbation rate, pre- and post-bronchodilator FEV₁ values, methacholine provocative dose causing a 20% fall in FEV₁, sputum and blood eosinophil counts and exhaled nitric oxide fraction (F_eNO) [83]. The best responders in terms of lung function can be identified on the basis of bronchodilator reversibility, blood and sputum eosinophil counts and high F_eNO levels [75, 84]. Features of airway remodelling, such as basement membrane thickening, which can be reverted by ICSs, were nonetheless shown as a limiting factor [85]. Bronchial vessels and airway smooth muscle layers were also shown to be reachable by corticosteroids [86, 87].

OCSs are specific to T2 airway inflammation

OCSs are mostly effective on T2 inflammation and changes in FEV₁ are often used to measure their effects, assuming the link between T2 inflammation and airway hyperresponsiveness. Conversely, long-term or regular OCS bursts are now becoming a T2 surrogate marker. Potentially, a low level of remaining eosinophilic inflammation might be considered in OCS-treated patients as predicting the benefit of a T2-targeted drug; a threshold of 150 cells·mm⁻³ in the blood has been often proposed [32, 33]. Incidentally, this supports the assumption that eosinophils are driving the disease in such cases. Since 2009, it has been known that having a T2 signature at the epithelial level is associated with a steroid-induced FEV₁ improvement. Actually, not all T2 cytokines share similar steroid sensitivity. In addition, the microbiome, when oriented towards Actinobacteria [51], is likely able to decrease steroid sensitivity. Recently, the simplistic view that T2 profile and OCS sensitivity are superimposed was challenged when alarmins such as IL-33 and thymic stromal lymphopoietin, thought to belong to the T2 axis, were shown to have poor steroid sensitivity. Finally, some patients have mixed steroid sensitive/insensitive signatures (e.g. combining T2 and T_H17 profiles).

Paediatric aspects

Use of daily OCSs in children seems unevenly distributed among a cohort of severe school and preschool-aged children with asthma among different countries, ranging from 0% to ∼25% [88–90]. Follow-up in an expert centre may explain the highest frequencies, as well as recruitment before the availability of biologics. Daily doses are extremely poorly reported but tend to be similar to those seen in adults with a median of 10 mg.

Bursts of OCSs in children are likely to be more frequent than in adults. In an analysis of health plan computerised claims data, 2–5% of children with asthma received three or more bursts per year, with more in the youngest (aged 1–8 years) than in the oldest children [91]. The frequent repeated prescription of OCS bursts in preschool-aged children with asthma (<4years of age) was also shown in a Dutch study [92]. In the school-aged children with severe asthma from the U-BIOPRED cohort, the median was 3 severe exacerbations requiring OCSs in the previous year [90]. In a French cohort of 104 children with severe allergic asthma treated with omalizumab, 68% had more than two bursts of OCSs for severe exacerbations in the year before the initiation of treatment [88]. Finally, in a study comparing the efficacy of daily home spirometry to a conventional strategy, conducted during 1 year in 50 French children with severe asthma and a history of frequent severe exacerbations, a median of three severe exacerbations (interquartile range (IQR) 1–4) and a median duration of treatment with systemic corticosteroids per patient for 12 days (IQR 4.0–22.0) were observed in the conventional arm.

Expressed as number of days on OCSs, it seems that adrenal insufficiency risk begins at around 20 days per year [38, 88–90, 93, 94]. Side-effects are nonspecific but probably more carefully assessed especially the slowing of the HPA axis in the visible way that it impairs and/or delays growth. Decreased bone density or associated surrogate marker and impaired glucose tolerance are also evident in children overexposed to OCSs, not necessarily exactly parallel to reported excessive weight gain [95–101].

Accordingly, OCS-sparing or, more appropriately, OCS-preventing strategies are extremely critical in children with severe asthma. New treatment strategies with biologics reduce daily systemic corticosteroids and OCS bursts, close to zero. This has been reported in real-life omalizumab studies in a large number of children with severe allergic asthma [93, 102]. However, these expensive drugs are not available all over the world and also not to preschool children [103]. Because low FEV₁ is associated with OCS use in adults, trajectories of FEV₁ are extremely meaningful for early identification of at-risk patients. Unfortunately, determinants of low FEV₁ during development and childhood are poorly identified (probably similar to what is known in COPD) [104]. In a cohort of children with mild-to-moderate asthma, asthma beginning in early life, frequent exacerbations, multiple allergic sensitisations, poor environment, and high bronchial hyperresponsiveness have been associated with airway growth impairment [104]. The impact of fetal exposure to tobacco and early-life viral infections, especially lower respiratory tract infections of respiratory syncytial virus on lung function has been highlighted. Furthermore, the efficacy of ICSs and also OCSs in preschool children with asthma is lower than in older children, because of different asthma pheno-/endotypes, indicating that other early and efficient interventions are an extremely urgent unmet need [105]. Moreover, the results of the ongoing trial with omalizumab, started 2 years ago, even in mild asthmatics with a positive modified Asthma Prediction Index are eagerly awaited, as well as strategies targeting viruses (vaccines, antiviral drugs) [106]. Similarly to what is currently claimed in adults, the usefulness of referral to expert centres is demonstrated but needs better implementation for routine procedures, especially in rural areas [107–109]. Flagging the yearly consumption of OCSs should be tested as a trigger for referral. Assessing surrogate markers of asthma drivers with the aim of initiating an OCS-sparing drug also looks obvious at this age.

Side-effects

Steroid side-effects are well known. They can appear with early-life exposures and last for the patient's entire life. Oral steroids are used in asthma at very high doses compared to most other inflammatory conditions, such as rheumatoid arthritis. The different modes of administration (e.g. inhaled, systemic, transcutaneous, nebulised, intranasal) probably exert cumulative effects because even local routes are associated with some level of systemic exposure, which is rarely, if ever, taken into account. Additional effects of high-dose ICSs should be better known. Recurrent bursts may have effects differing from those of long-term daily exposure, but this remains to be further explored in real-life studies. Individual susceptibility to steroid side-effects is extremely heterogeneous [110], which supports the need for additional tests. These could be based on epigenetic modifications and/or pharmacogenetic findings. Costs associated with the prevention and management of steroid side-effects should be considered, while discussing the cost-effectiveness of corticosteroid-sparing strategies.

Common corticosteroid side-effects

Cushing syndrome and adrenal insufficiency

Many unmet needs persist around adrenal insufficiency [132, 133]. Adrenal glands are called “the gland of stress”. They are made of two distinct tissues: 1) the central medulla derives from the neuro-ectoderm and produces catecholamines; 2) the cortex derives from the intermediate mesoderm and is characterised by its activity of steroidogenesis [134]. Progenitor cells are found within the mesenchymal capsule and are embedded in the outermost cortical zone. The cortex is divided into three distinct zones. The outer zona glomerulosa produces mineralocorticoids (aldosterone), the zona fasciculata produces GCs (cortisol) and the zona reticularis produces adrenal androgens (dihydroepiandrosterone). GC production is stimulated by adrenocorticotropic hormone (ACTH) within a well-known negative feedback loop orchestrated by the pituitary gland, in response to hypothalamic corticotropin-releasing hormone release. Both ACTH and GC releases are cyclic, with a zenith in the morning and nadir in the middle of the night.

Synthetic GCs face problematic side-effects, especially at high doses and in the long term [135]. In these situations, they lead to iatrogenic Cushing syndrome. In a manner reminiscent of primary Cushing syndrome, resulting from hyperactivity of the zona fasciculata of the adrenal cortex, iatrogenic Cushing syndrome is associated with osteoporosis, skin atrophy, diabetes, hypertension, abdominal obesity, acne, increased susceptibility to infections, stunting and high blood pressure. The deleterious psychiatric effects and bone fragility associated with Cushing syndrome can persist after normalisation of GC levels. Beyond iatrogenic Cushing syndrome [136], suppression of the HPA axis associated with chronic treatment with synthetic GCs leads to more or less pronounced adrenal insufficiency at the end of treatment. The depth of adrenal involvement depends on the dose, method of administration and duration of treatment. It may persist for >12 months after discontinuation of therapy. The clinical presentation of adrenal deficiency is often insidious and includes nonspecific symptoms such as fatigue, nausea, vomiting and diarrhoea, muscle weakness, weight loss and potentially hypoglycaemia. The secretion of renin-controlled aldosterone is maintained, and the onset of hyperpigmentation characteristic of Addison disease is not observed, as ACTH secretion is blunted in response to synthetic GCs. Adrenal insufficiency can lead to a potentially lethal adrenal crisis in the absence of treatment.

If inhibition of ACTH secretion can account for adrenal atrophy during the course of treatment, the persistence of insufficiency several months after its termination is difficult to explain. This may result from a failure to regain the pulsatile secretion of ACTH or a difficulty of the adrenal gland to compensate for the atrophy induced by long-term treatment. Data in a mouse model of chronic dexamethasone treatment for 14 days show that adrenals initially undergo apoptosis but have the capacity to fully regenerate over 2 weeks, by mobilising SHH⁺ and GLI1⁺ progenitor cells in a WNT/β-catenin dependent manner [137]. However, whether longer term treatment with GCs would result in complete inhibition of the adrenal regeneration machinery is still unclear. Interestingly though, recent data have shown that protein kinase A signalling responsiveness and zF differentiation are programmed by the epigenetic regulator EZH2 through deposition of the H3K27me3 histone mark [138]. It is therefore tempting to speculate that prolonged GC exposure may alter EZH2 activity, which could result in aberrant epigenetic reprogramming of protein kinase A signalling within the adrenal and durable zF activity suppression.

Another puzzling aspect of adrenal insufficiency in patients receiving chronic corticosteroid therapy is the heterogeneity of response. A recent genome-wide association study has demonstrated that single nucleotide polymorphism in the platelet-dervied growth factor D locus were associated with an increased susceptibility to AI in children with asthma and adults with COPD [139]. Interestingly, deletion of both PDGF receptors α and β in steroidogenic tissues results in abnormal development of the adrenal steroidogenic compartment [140]. This suggests that variants in PDGFD may have an impact on adrenal development/differentiation, which would account for variations in insufficiency in response to prolonged GC exposure. Negative impact of systemic corticosteroid on growth is clearly known [95, 141]. In contrast, the potential but small adverse effect of ICSs must be weighed against the large established benefit of these drugs to control persistent asthma [142]. It is linked to the daily dose when ICSs are prescribed at low-to-medium doses, according to the guidelines. Impact of repeated OCS bursts and daily systemic corticosteroids is far higher.

Under-appreciated side-effects

Many facets of severe asthma burden can relate directly or indirectly to GC exposure [143]. Sleep disturbance, anxiety and depression and other psychiatric/mood disorders, skin bruising, sore mouth, dental problems and weight gain; its consequence are highlighted by patients [144] and are frequently underestimated by physicians. These effects strongly impact quality of life. Fear of side-effects may induce a vicious circle related to poor adherence and poor control as well as medical nomadism [23]. In children, adverse behavioural effects of OCS bursts prescribed in asthma exacerbations have also been shown [145].

Identification of patients

OCS consumption is difficult to accurately estimate and considerable discrepancies may exist between quantities of dispensed versus actually consumed drugs. Additionally, related thresholds or “flags” for referral are not clearly identified in primary care. The concept of “asthma control” was raised nearly 40 years ago, but unfortunately was poorly integrated by patients and primary care personnel. Given this context, we felt that an opportunity existed to involve patients and pharmacists in the establishment of proposed referral thresholds, with an easy-to-recall “yellow flag” at 500 mg·year⁻¹ for at-risk patients (obese, diabetic, osteoporotic or paediatric patients, for example) and a “red flag” at 1 g·year⁻¹ for all patients. Personalising OCS-associated risk levels should then be proposed at this stage, for example via a specifically designed score [108].

Once identified, these patients should be assessed for a number of issues addressed in secondary care environments. OCS overuse is frequent and can substantially benefit from a multidisciplinary approach towards asthma [107]: improved adhesion to prescribed maintenance therapy, removal of a persistent exposure to known triggers (particularly allergens or pets), improving poor inhalation technique, or the discovery of untreated comorbidities. Still central and requiring multiple expertise (frequently including a psychologist/psychiatrist), OCS overuse may also result from misdiagnosis and interpretation of symptoms not necessarily caused by asthma [145]. The latter may sometimes require a justification of each OCS burst by an external adviser. For those admitted to the intensive care unit during previous tapering attempts, and those with features of specific diseases such as EGPA or allergic bronchopulmonary aspergillosis, it seems reasonable to recommend referring them to dedicated tertiary centres.

Initiate OCS tapering

Once the above-mentioned assessments and optimisations are successfully deployed, optimising management frequently relies on maximising the ICS dose, even though this concept may appear challenging in these patients, as discussed in the first part of this review. This may be achieved through maintenance and reliever therapy strategies. Adding another controller(s) is also recommended. Education and psychological support are key options for leveraging the chances of successful OCS weaning within a shared decision-making process. Eligibility for currently available therapeutic options can be conducted in parallel and repeated at each step of the tapering plan. We recommend systematic supervision of the OCS-tapering phase. Using objective markers of disease activity would secure the rhythm of tapering and provide key clues in the eventual reasons implicated in case of failure. Unfortunately, the “ideal” marker(s) of disease activity during an OCS-tapering phase is unknown. Whether the combination of FEV₁ value, symptoms and rescue medication use will be replaced or improved by a relevant biomarker is a key question to address in the future. Since 2002, there has been evidence that use of sputum eosinophils to titrate corticosteroid dose results in better outcomes [150], suggesting the poor specificity of symptoms when considered alone. Symptoms are often due to nonasthma-related factors (i.e. obesity) and might therefore not be the best method to assess patients during OCS tapering. Beyond biological signatures associated with adrenal insufficiency, T2-related biomarkers (F_eNO, blood or sputum eosinophil counts) are OCS-sensitive in general and the maintenance of their silencing during a tapering phase should be tested.

Initiate OCS-sparing therapy and assess the response

In patients where all the previous mandatory steps could be assessed and optimally addressed, the addition of an OCS-sparing therapy is expected to not only decrease the daily maintenance dose of OCSs but also to simultaneously reduce exacerbation rates (which in itself may also further contribute to reducing overall OCS exposure [31–33]). OCS-sparing therapies may also improve certain comorbidities, frequently treated by topical or systemic corticosteroids, such as eosinophilic oesophagitis, atopic dermatitis, urticaria, nasal polyps and EGPA. Now that multiple options are available and most of the associated biomarkers are overlapping, establishing clear stopping rules at the initiation of such therapy is becoming mandatory. In light of the burdens associated with OCS use, it was estimated that OCS weaning should take first place among the goals of biological therapy. Accordingly, we considered that a 50% decrease in OCS dose, while certainly acknowledgeable, remained an unacceptable outcome, given the risks of any maintenance OCS dose. Moreover, since multiple therapeutic options are available, we then consensually agreed that failure-to-wean justifies consideration for switching biological therapies (under the supervision of an expert as it was shown to be feasible and safe). Adrenal insufficiency and the emergence of OCS-masked associated diseases during tapering, such as EGPA or allergic bronchopulmonary aspergillosis should explain most of the clinical failures in eligible patients, except cases of addiction or the development of antidrug antibodies. The need for continuous, strict screening and management of OCS-related adverse events in these patients is recalled and emphasised.