key: cord-1056296-xvbgwe01
authors: Romanou, Vasiliki; Koukaki, Evangelia; Chantziara, Vasiliki; Stamou, Panagiota; Kote, Alexandra; Vasileiadis, Ioannis; Koutsoukou, Antonia; Rovina, Nikoletta
title: Dexamethasone in the Treatment of COVID-19: Primus Inter Pares?
date: 2021-06-15
journal: J Pers Med
DOI: 10.3390/jpm11060556
sha: 64b705291e72499ecc01934ace8acb88dea521d4
doc_id: 1056296
cord_uid: xvbgwe01

Coronavirus disease 2019 (COVID-19), caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has rapidly spread globally, becoming a huge public health challenge. Even though the vast majority of patients are asymptomatic, some patients present with pneumonia, acute respiratory distress syndrome (ARDS), septic shock, and death. It has been shown in several studies that the severity and clinical outcomes are related to dysregulated antiviral immunity and enhanced and persistent systemic inflammation. Corticosteroids have been used for the treatment of COVID-19 patients, as they are reported to elicit benefits by reducing lung inflammation and inflammation-induced lung injury. Dexamethasone has gained a major role in the therapeutic algorithm of patients with COVID-19 pneumonia requiring supplemental oxygen or on mechanical ventilation. Its wide anti-inflammatory action seems to form the basis for its beneficial action, taming the overwhelming “cytokine storm”. Amid a plethora of scientific research on therapeutic options for COVID-19, there are still unanswered questions about the right timing, right dosing, and right duration of the corticosteroid treatment. The aim of this review article was to summarize the data on the dexamethasone treatment in COVID-19 and outline the clinical considerations of corticosteroid therapy in these patients.

Coronavirus disease 2019 , caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has rapidly spread around the world since its first appearance in China [1] [2] [3] . Although the vast majority of patients present with mild symptoms, about 15% of COVID-19 cases become severe [4] , with approximately 31-41.8% of hospitalized patients rapidly developing acute respiratory distress syndrome (ARDS) [1, 2] with a subsequent increased risk of death. The mortality rates referring to critically ill COVID-19 patients range between 26% and 61.5% around the world [1] [2] [3] [4] .

Several studies have documented that the severity and clinical outcomes are related to dysregulated antiviral immunity and enhanced and persistent systemic inflammation [5] [6] [7] [8] [9] , as highlighted by a decreased expression of interferons I/III and hyperinflammatory responses involving the release of proinflammatory cytokines (e.g., IL-6, IL-1, TNF, IL-8, and MCP-1) that are sustaining in time (cytokine storm). Consequently, antiviral and anti-inflammatory therapies have been implemented in the pursuit of timely and effective therapies. As yet, though, no specific pharmacological treatments have been proven efficacious for the treatment of COVID-19 [10] .

In the context of inflammation being a key role player in the evolvement of severe disease, corticosteroids have been used for the treatment of COVID-19 patients, as they are reported to elicit benefits by reducing lung inflammation and inflammation-induced lung injury. Early enough, in the first pandemic wave, corticosteroids were introduced in the treatment of critically ill COVID-19 patients with respiratory failure in low-tomoderate doses and for short courses [4, [11] [12] [13] . Wu et al. showed that the corticosteroid treatment in patients with ARDS reduced the mortality risk (46% in patients receiving corticosteroids vs. 61.8% in patients not receiving corticosteroids [14] . Furthermore, the Surviving Sepsis Campaign suggests the use of low-dose corticosteroid therapy in COVID-19 patients with refractory shock to suppress the cytokine storm caused by SARS-CoV-2 and to improve peripheral vasodilation [15] . With the RECOVERY trial, a significant benefit of glucocorticoid dexamethasone was shown in patients with COVID-19 on mechanical ventilation or oxygen alone at the time of randomization [16] . Based on the positive results of the RECOVERY trial, the National Institutes of Health (NIH) COVID-19 Treatment Guidelines and the World Health Organization (WHO) approved the findings on the beneficial use of dexamethasone in treating critically ill patients with COVID-19 and recommended the dexamethasone treatment in hospitalized patients with respiratory failure requiring a noninvasive/high-flow oxygen device or invasive ventilation [17] . Nonetheless, several studies have reported deleterious effects caused by the corticosteroid treatment that was associated with the use of an increased dose of corticosteroids [18] [19] [20] , the delay of SARS-CoV-2 viral clearance in patients receiving corticosteroids [18, 21] , and the increased risk of secondary infections and complications due to the corticosteroid treatment. Therefore, the clinical benefit of this treatment in COVID-19 patients still remains controversial.

Beyond doubt, the RECOVERY trial showed a clear benefit of dexamethasone in critically ill patients with COVID-19 on mechanical ventilation at the time of randomization as compared to the usual care (28-day mortality of 29.3% vs. 41.4%). Similarly, patients on oxygen alone in the dexamethasone group, when compared to the usual care group, had a lower risk of progression to invasive mechanical ventilation (risk ratio, 0.79; 95% CI, 0.64 to 0.97), a shorter duration of hospitalization (median, 12 days vs. 13 days), and a greater probability of being alive at discharge within 28 days (rate ratio, 1.10; 95% CI, 1.03 to 1.17) . No benefit was shown in patients with a milder disease without respiratory failure (28-day mortality of 17.8% vs. 14%) [16] .

Two more observational trials of corticosteroids for COVID-19 [14, 22] and four review and meta-analysis studies [23] [24] [25] [26] showed evidence of benefits in mortality. Of note, Pasin et al. in their metanalysis [24] of the five basic studies on corticosteroids ikn COVID-19 [16, [27] [28] [29] [30] coincided with the RECOVERY trial results in that the survival benefits of corticosteroids exist for mechanically ventilated patients and not for patients with no oxygen need. In line with these positive results, subgroups of COVID-19 patients with ARDS [31, 32] , increased inflammatory markers [33] , or over 60 years of age [30] had the highest benefits from corticosteroids. Improved clinical symptoms, radiological findings, and the respiratory failure of patients with COVID-19 were also reported [34, 35] . In a small randomized controlled trial, improved clinical outcomes were reported in patients with COVID-19 receiving a short course of methylprednisolone [13] . Wang et al. [35] also found that the use of methylprednisolone (1 to 2 mg/kg/day for 5-7 days) in twenty-six severe COVID-19 patients was associated with a reduced length of hospitalization and ICU stay.

Collectively, a prospective meta-analysis of the trials by the WHO, with a total of 1703 patients (59% from the RECOVERY trial), confirmed a reduction in the 28-day mortality (summary odds ratio (OR) 0.66, 95% CI 0.53-0.82; p < 0.001) [23] .

Nevertheless, the mortality benefits of corticosteroids were not confirmed in a series of other studies [27, 28, 30, [36] [37] [38] [39] . The retrospective cohorts of COVID-19 patients, mostly from the first wave in China [18, 19, 40, 41] , reported an increased mortality in severely ill patients taking high-dose corticosteroids. Lu, X. et al. [19] mentioned that a 10-mg increase in hydrocortisone resulted in a 4% increase in the risk of death. In accordance were the results of one meta-analysis study [20] based on low-quality evidence with a high variability. Tables 1-4 summarizes the trials on corticosteroid treatments in COVID-19 patients. These results should be interpreted with caution owing to the potential bias and confounding factors, since they mostly derive from small-sized single-center observational studies; they include patients of different disease stages or severities, and furthermore, they refer to corticosteroid treatments other than dexamethasone. It is noteworthy that dexamethasone showed favorable results in the RECOVERY trial, especially in the critically ill patients, setting a novel positive view on corticosteroid use in respiratory viral infections in these patients. Hence, understanding dexamethasone's mode of action merits the uppermost importance. Table 1 . Trials using methylprednisolone (MP); by design (R = randomized in blue and Rs = retrospective and obs = observational in yellow), timing, duration, outcomes (focusing on mortality data), and viral shedding. Table 3 . Trials using hydrocortisone (HC); design (R = randomized in blue), timing, duration, outcomes (focusing on mortality data), and viral shedding. Table 4 . Trials using different corticosteroids (CS); design (Rs = retrospective and obs = observational and As = ambispective in yellow and MA = meta-analysis and SRMA = Systematic Review and Meta-analysis in orange), timing, duration, outcomes (focusing on mortality data), and viral shedding. 

Corticosteroids are known to temper down the host inflammatory response in the lungs, which may lead to acute lung injury and ARDS [52] . They exert their anti-inflammatory effects by binding to their receptor, the glucocorticoid receptor-GR. GR is a ligand-activated transcription factor whose signaling plays a key role in the modulation of numerous biological functions of the immune cells. Upon ligand binding, GR translocates to the nucleus, where it can enhance transcription by binding to glucocorticoid response elements (GREs). On the other hand, GR, when tethering directly to negative glucocorticoid response elements (nGREs) or GRE half-sites or by binding to transcription factors such as NF-κB, may repress the expression of several genes [53] . Thus, it is evident that the corticosteroid treatment is a double-edged sword, which may induce or inhibit inflammatory cell activity. Several studies have shown that corticosteroids may inhibit T-lymphocyte immunity, an important antiviral mechanism, resulting in persistent viral replication and a delay in viral clearance. At the same time, the suppression of proinflammatory cytokines such as TNF, interleukins, and other genes, such as cyclooxygenase-2 and inducible nitric oxide synthase (iNOS), and the inhibition of the neutrophils, macrophages, and lymphocytes inflammatory activity are documented as effects of corticosteroid use [54] .

Dexamethasone has both anti-inflammatory and immunosuppressive effects. Specifically, when binding to GR, it initiates a cascade of immune cell responses that lead to the suppression of proinflammatory cytokines, such as IL-1, IL-6, IL-8, TNF, and IFN-γ, by inhibiting gene transcription [54] . In the case of SARS-CoV-2 infection, those are the produced proinflammatory cytokines that result in local tissue inflammation and in the socalled "cytokine storm" [55] . Furthermore, dexamethasone exerts anti-inflammatory effects by inhibiting macrophage activation [56] , neutrophil's adhesion to endothelial cells, and the release of lysosomal enzymes, preventing chemotaxis at the site of inflammation. Finally, it increases IL-10 gene expression, thus exhibiting further anti-inflammatory effects [57] .

Another important function of dexamethasone is its implication in the process of the resolution of inflammation by inducing the D-series pro-resolving lipid mediator pathway via the formation of protectins D1 and DX7 and of 17S-dihydroxydocosahexaenoic acid (17S-HDHA) [58] . These agents have documented roles in driving the resolution of inflammation by regulating the termination of proinflammatory responses, the removal of inflammatory cells, and the tissue repair mechanisms [59] . Finally, certain lipid mediators have been shown to diminish pathologic thrombosis and NETosis, decrease the levels of procoagulant factors and fibrinogen, enhance the removal of clots, and increase the anticoagulant factors [60] . These functions are of high importance, since the thrombotic pathways are central in the pathology of COVID-19 infection.

Overall, in critical COVID-19 patients, glucocorticoid therapy exerts several functions, such as effective homeostatic corrections and consequent improvement in the critical illnessrelated corticosteroid insufficiency (CIRCI), control of inflammation, and stabilization of cardiovascular and metabolic functions. Furthermore, it induces increased mitochondrial biogenesis, corrects the content and functions of the mitochondria, and decreases the devastating tissue oxidation that leads to multiple tissue and organ dysfunctions [61] .

Starting with the main results of the RECOVERY trial, the most robust until now, that gave dexamethasone a central role in the treatment of COVID-19, dexamethasone at a dose of 6 mg per day for ten days was effective at reducing the mortality rate in both ventilated and oxygenated patients by one-third and one-fifth, respectively, compared to the usual care alone [16] .

However, several questions relative to corticosteroid therapy arose:

1.

Why use dexamethasone instead of other corticosteroids? 2.

When to start corticosteroids?

At what dose and for how long? 4.

Do they prolong viral shedding?

How safe are corticosteroids in the treatment of severely affected COVID-19 patients? 6.

What is the role of inhaled corticosteroids in preventing or treating COVID-19 patients? 7.

Why use dexamethasone instead of other corticosteroids?

Pharmacologically, dexamethasone has a more advantageous pharmacokinetic/pharmacodynamic (PK/PD) profile. Dexamethasone is a long-acting synthetic corticosteroid with systemic effects and is almost 25 times more potent than other synthetic corticosteroids, as depicted by the equivalent steroid doses (40-mg hydrocortisone:10-mg prednisolone:8-mg methylprednisolone:1.5-mg dexamethasone) [62] .

Dexamethasone's higher potency is explained by its higher affinity for the glucocorticoid receptor compared to other steroids, leading to a more profound genomic and metagenomic activity [62] [63] [64] and consequent greater inhibition of the proinflammatory pathways. Additionally, it possesses minimal mineral corticoid activity, limiting the undesired retention of the fluid and sodium. On the PK side, dexamethasone has a longer half-life of 36-72 h, allowing for once-daily dosing [65] .

The time of corticosteroid treatment initiation is of great importance in order to have favorable outcomes. Siddiqi and Mehra [66] suggested three escalating phases of COVID-19 disease progression, with associated signs, symptoms, and potential phase-specific treatments: the early infection phase, the pulmonary phase, and the hyperinflammation phase, in which anti-inflammatory treatments (such as corticosteroids) are recommended as beneficial. Indeed, in the RECOVERY trial [16] , a clear benefit was shown in the patients who were treated with dexamethasone for more than 7 days after symptom onset, when inflammatory lung damage was likely to be more common, and not among those with more recent symptom onsets. It is evident that randomized controlled trials are needed in order to clarify the right timing for the initiation of a corticosteroid treatment course.

Another consideration is whether "one size fits all" and how effective dexamethasone is in the dose of 6 mg/day for ten days in all COVID-19 patients with respiratory failure, irrespectively of them developing ARDS or not. This daily dose is considered low, with few adverse events [39] , as opposed to the 20-40 mg needed daily for hematologic malignancies, autoimmune diseases, or shock.

In an early single-center observational study in Wuhan [61] , there was a lower risk of death in the patients who received low-dose corticosteroids (<1 mg/kg/day) or no corticosteroids at all compared to high-dose regimens, but the difference was not statistically significant.

In the CoDEX randomized trial in patients with COVID-19 with moderate-to-severe ARDS, the dose of dexamethasone administered (20 mg of dexamethasone intravenously daily for 5 days and 10 mg of dexamethasone daily for 5 days or until ICU discharge) [27] was higher than that used in the RECOVERY trial. The selection of this higher dose was based on the design of a previous study [67] in patients with non-COVID-19 ARDS who were treated with dexamethasone (or equivalent) in the dose of 30 mg/day. Eventually, a statistically significant increase in the number of ventilator-free days (days alive and free of mechanical ventilation) was shown over 28 days, with a good safety profile [27] .

Furthermore, Papamanoli et al. [43] showed that, in nonintubated patients with severe COVID-19 pneumonia, higher doses of methylprednisolone (160 mg for a median duration of approximately 10 days) were associated with a lower risk for mechanical ventilation or death (37%) and without consequent adverse effects. Interestingly, among the intubated patients, those that were treated with corticosteroids had more ventilator-free days and shorter length of ICU stays compared to the patients not receiving corticosteroids.

Fernandez-Cruz et al. [32] showed lower in-hospital mortalities in patients with SARS-CoV-2 pneumonia treated with corticosteroids, no matter if they received an initial regimen of 1 mg/kg/day of methylprednisolone or with corticosteroid pulses.

A more recent review and meta-analysis of 35 studies by Cano et al. [26] depicted the high heterogeneity of the practices in dosing steroids; in 74.2% of the studies, steroids were given in low doses, in 11.4%, in high or pulse doses, and in 5.6%, a mixed regimen was used. The meta-analysis failed to prove a beneficial or harmful effect of either dosing scheme.

To complicate the dosing dilemmas further, the published data showed that serum albumin plasma levels, competing drugs, and albumin glycation are important clinical variables influencing the effectiveness of dexamethasone in treating COVID-19 patients [68] . Each one of these factors decreases the binding capacity of albumin, complicating the transport capacity of dexamethasone and resulting in a shorter half-life of the drug and potential toxicity at its peak concentration. It might be appropriate to modify the dose of dexamethasone according to the albumin levels, patient's weight, and/or plasma levels in order to achieve the therapeutic levels and to avoid toxicity [69] .

From a pathophysiology point of view, as Chrousos and Meduri concluded, corticosteroid administration in severe COVID-19 should start early, before the irreversible exhaustion of homeostatic reserves, with large doses to saturate the ubiquitous glucocorticoid receptors, so that the maximum effect is attained [70, 71] . Following precision medicine, the dosing of corticosteroids should be tailored to each patients' unique manifestations, as Gogali et al. explained [72] . From the evidence-based medicine side, though, it is evident that the optimal corticosteroid dosing and duration of treatment still need clarification, especially in critically ill COVID-19 patients with ARDS. Towards this direction, the results of currently undergoing trials like "HIGHLOWDEXA" [20] , assessing the efficacy of high doses of dexamethasone (20 mg/day for 5 days and then 10 mg/day for 5 days) vs. low doses of dexamethasone (6 mg/day for 10 days) in patients with respiratory failure might shed more light on the therapeutic algorithms of severe COVID-19.

An analysis of the retrospective observational studies from the first pandemic wave showed results associating corticosteroids with immune suppression, an increased viral load, delayed clearance from the body, and increased mortality [21, 22] . The early administration of corticosteroids in non-severely ill patients may be deleterious due to an increase of viral shedding or a delay in viral clearance [46] . Prolonged viral shedding has been supported by several retrospective studies [14, 36] . Notably, nonsevere COVID-19 pneumonia patients who received early corticosteroid treatment had a more prolonged viral shedding compared to patients of similar severity who did not receive corticosteroids, as was shown in two cohorts [47, 48] and one randomized study [42] . A recent review and meta-analysis of 15 studies examining, among others, the SARS-CoV-2 clearance concluded a delay in viral clearance in patients receiving corticosteroids compared with patients who did not receive corticosteroids but failed to prove a statistical significance [20] . Importantly, there are implications that viral shedding prolongation follows a dose-dependent scheme of corticosteroids [49] . However, this theory was not confirmed in the study of Fang et al. [51] , who used a low dose of corticosteroids in patients with COVID-19; there was no significant difference in the duration of viral shedding between patients receiving and patients not receiving corticosteroids, irrespective of the severity of the disease. Accordingly, no significant difference in the viral clearance was shown in other studies [22, 30, 37, 38, 45] . Two retrospective studies by Xu, K. and Shi, D. [73, 74] concluded that corticosteroids were not independent predictors of prolonged viral shedding as opposed to the male sex, lymphocytopenia, APACHE score, and IVIG treatment.

To sum up, there is no clear conclusion as to whether corticosteroids delay the SARS-CoV-2 clearance, and more importantly, there is no certainty about the clinical significance of this.

The long-term use of corticosteroids has well-established adverse effects. The shortterm use of steroids, although frequent in the pre-pandemic era, was only recently exam-ined for its potential adverse effects. Two large population-based studies in adults, an American [50] and a Chinese [75] one, underline the increased risk of complications in the outpatient setting. Waljee et al. [50] concluded that, within 30 days of steroid initiation, there was a two to five-fold increase in the incidence rates of fractures, venous thromboembolism, and admission for sepsis, in that order of frequency, in steroid users 18-64 years of age compared to non-users. Yao et al. [75] found a significant increase in gastrointestinal bleeding, sepsis, and heart failure in the respective Chinese population.

Currently the recommendations on corticosteroid use in COVID-19 concern severely ill inpatients requiring O 2 or mechanical ventilation and definitely not outpatients. Is this sicker population threatened by the same harms of short-term corticosteroids use as the general population? The existing literature on COVID-19, although abundant, is not centered on adverse events.

Certain studies concluded that there were no significant differences in serious adverse events between corticosteroid and the standard-of-care groups [24, 27, 37, 42, 45, 46] , while others pointed to a greater probability of myocardial or liver injury, shock [21] , and agitation [23] in corticosteroid-treated COVID-19 patients.

Supporting the safety of corticosteroids, the RECOVERY trial [16] reported a similar incidence of new cardiac arrhythmia in the dexamethasone group and the usual care group. In a total of 2104 patients, there were four reports of serious adverse reactions that were deemed by the investigators to be related to dexamethasone: two of hyperglycemia, one of gastrointestinal hemorrhage, and one of psychosis (all recognized adverse effects of corticosteroids).

In the CAPE COVID trial [28] , which was stopped early after the publication of the results from the RECOVERY trial, the administration of a low dose hydrocortisone in 148 patients was followed by three serious events: one was cerebral vasculitis, attributed to the SARS-CoV-2 itself, the second was an episode of pulmonary embolism with cardiac arrest, which was considered single and unrelated to steroids, and the third event was an intrabdominal hemorrhage related to anticoagulation for pulmonary embolism.

In REMAP-CAP [29] , the only adverse events that were considered relevant to the corticosteroid treatment were one event of neuromyopathy and one event of fungemia.

The recently published results of the OUTCOMEREA network [76] showed that COVID-19 critically ill patients have a higher risk for bloodstream infections (BSI) than their non-COVID-19 counterparts after 7 days of ICU stay, but this negative event was associated with the use of anti-IL-1 and anti-IL-6 and not to corticosteroids. Similarly, no difference in BSI incidence was detected in the MetCOVID randomized trial [30] or the retrospective study by Papamanoli et al. [43] .

On the contrary, Giacobbe et al. [77] in their retrospective single-center study, found a higher BSI risk for corticosteroid-treated patients (csHR 3.95, 95% CI 1.2-13.03) than those receiving only tocilizumab (csHR 1.07, 95% CI 0.38-3.04), the risk being even higher with their combination (csHR 10.69, 95% CI 2. 71-42.17) .

The clinical research points towards an association between corticosteroid use and secondary infections. More secondary infections with sepsis have been recorded [26, 36] , but the difference was not always significant [13] . The indirect evidence on increased secondary infections may come from the increased antibiotic use in corticosteroid-treated patients, as two retrospective studies [47, 48] and one systematic review and meta-analyses [26] have shown.

The literature is more extensive on fungal infections in COVID-19 patients. Corticosteroid treatment is a well-known risk factor for invasive mycoses [78] . An excellent review of retrospective studies from China and Europe reported a 20-35% incidence of COVID-19-associated pulmonary aspergillosis (CAPA) [79] A case report of mucormycosis following the treatment with dexamethasone was reported in a 44-year-old diabetic woman [80] raising concerns about the duration and dosing of the corticosteroid treatment in diabetic COVID-19 patients. Hyperglycemia, which led to increased doses of insulin, was mentioned in most studies [13, 23, 30, 42] as an adverse event of the corticosteroid treatment as expected, but it was not severe [27] .

Reviewing the literature concerning the adverse events of corticosteroid treatment in COVID-19 patients, we underline a significant deficit, as safety is not among the primary outcomes of most studies. This is not a surprise, because corticosteroids are used extensively, and physicians are very familiar with their use. Additionally, some of the main adverse effects of corticosteroids (i.e., VTE, secondary infections and GI hemorrhage) are the main COVID-19 complications or harms from other necessary treatments (i.e., anticoagulation), and perhaps, it is difficult to discriminate the proportional contribution of the virus or the steroids.

Targeting a safe treatment alternative to systemic corticosteroids, inhaled corticosteroids (ICS) have been proposed. There is a cumulative experience of ICS in chronic airways diseases like asthma and COPD, linking their use to changes in the microbiome and, finally, to the increased frequency of upper and lower respiratory tract infections [81, 82] . However, an association of ICS with the susceptibility to viral infections is lacking. Instead, a paradoxical protection against viral infections has risen [83, 84] . Ciclesonide seems to block SARS-CoV-2 replication in vitro, and in addition, it impedes its cytopathogenicity [85, 86] . Early-stage COVID-19 treatment with inhaled corticosteroids might inhibit the progression of SARS-CoV-2 infection to COVID-19. This was shown in a small study of COVID-19 patients on oxygen (not mechanically ventilated) who improved after the treatment with inhaled ciclesonide [87] Similarly, there was in vitro evidence of budesonide's direct antiviral and anti-inflammatory properties [88] . In the recent open-label, in parallel groups, phase 2 randomized control trial in mild outpatient COVID-19 patients that received inhaled budesonide vs. the usual care, a 91% reduction in the relative risk for COVID-19-related urgent care or hospitalization was shown in the budesonide-treated patients [89] .

Patients with chronic lung disease, often on long-term ICS, form a special subcategory of COVID-19 patients. A systematic review of the patients with coronavirus acute respiratory infections (MERS, SARS and COVID-19) by Halpin et al. [90] did not reach a clear-cut conclusion as to whether premorbid use or the continuous administration of ICS is a benefit. Currently, there is a suggestion against the withdrawal of chronically used ICS; asthma and COPD patients receiving ICS are advised to carry on with their treatments [91, 92] . Table 5 summarizes the commonest reported adverse events. CS: ↑ use of antibiotics and ↑ secondary infections or sepsis BC = blood culture, BSI = bloodstream infections, esp = especially, GI = gastrointestinal, ↑ Glu = hyperglycemia, IA = intra-abdominal, PE = pulmonary embolism, and VAP = ventilator-associated pneumonia.

CNS=central nervous system; CVS: cardiovascular system.

In conclusion, dexamethasone has gained a major role in the therapeutic algorithm of patients with COVID-19 pneumonia requiring supplemental oxygen or on mechanical ventilation. Its wide anti-inflammatory action seems to form the basis for its beneficial action, taming the overwhelming "cytokine storm". Amid a plethora of scientific research on the therapeutic options for COVID-19, there are still unanswered questions about the right timing, right dosing, and right duration of corticosteroids. Lastly, since medicines treat patients, we urgently need more evidence on the safety of corticosteroids on specific patient populations who may be at risk for more complications. 

Epidemiological and clinical characteristics of 99 cases of 2019 novel coronavirus pneumonia in Wuhan, China: A descriptive study

Clinical features of patients infected with 2019 novel coronavirus in

A Novel Coronavirus from Patients with Pneumonia in China

China Medical Treatment Expert Group for COVID-19. Clinical Characteristics of Coronavirus Disease 2019 in China

Impaired type I interferon activity and inflammatory responses in severe COVID-19 patients

Untuned antiviral immunity in COVID-19 revealed by temporal type I/III interferon patterns and flu comparison

Complex Immune Dysregulation in COVID-19 Patients with Severe Respiratory Failure

Interferon deficiency can lead to severe COVID

COVID-19: Consider cytokine storm syndromes and immunosuppression

Clinical Management of COVID-19

Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: A single-center, retrospective, observational study

On the use of corticosteroids for 2019-nCoV pneumonia

GLUCOCOVID investigators. Methylprednisolone in adults hospitalized with COVID-19 pneumonia: An open-label randomized trial (GLUCOCOVID)

Corticosteroid therapy for coronavirus disease 2019-related acute respiratory distress syndrome: A cohort study with propensity score analysis

Dexamethasone in hospitalized patients with COVID-19. The RECOVERY Collaborative Group

World Health Organization. WHO Welcomes Preliminary Results about Dexamethasone Use in Treating Critically Ill COVID-19 Patients

Corticosteroid treatment in severe COVID-19 patients with acute respiratory distress syndrome

Adjuvant corticosteroid therapy for critically ill patients with COVID-19

Low or High Dose of Dexamethasone in Patients with Respiratory Failure by COVID-19 (HIGHLOWDEXA)

Effects of methylprednisolone on viral genomic nucleic acid negative conversion and CT imaging lesion absorption in COVID-19 patients under 50 years old

Prolonged low-dose methylprednisolone in patients with severe COVID-19 pneumonia

WHO Rapid Evidence Appraisal for COVID-19 Therapies (REACT) Working Group. Association between Administration of Systemic Corticosteroids and Mortality among Critically Ill Patients with COVID-19: A Meta-analysis

Corticosteroids for patients with coronavirus disease 2019 (COVID-19) with different disease severity: A meta-analysis of randomized clinical trials

Corticosteroid use in COVID-19 patients: A systematic review and meta-analysis on clinical outcomes

Effect of dexamethasone on days alive and ventilator-free in patients with moderate or severe acute respiratory distress syndrome and COVID-19: The CoDEX randomized clinical trial

Effect of Hydrocortisone on 21-Day Mortality or Respiratory Support among Critically Ill Patients with COVID-19: A Randomized Clinical Trial

Corticosteroid Domain Randomized Clinical Trial

A randomized, double-blind, phase IIb

Risk Factors Associated with Acute Respiratory Distress Syndrome and Death in Patients with Coronavirus Disease

A Retrospective Controlled Cohort Study of the Impact of Glucocorticoid Treatment in SARS-CoV-2 Infection Mortality

Effect of systemic glucocorticoids on mortality or mechanical ventilation in patients with COVID-19

Potential benefits of precise corticosteroids therapy for severe 2019-nCoV pneumonia

A retrospective cohort study of methylprednisolone therapy in severe patients with COVID-19 pneumonia

Corticosteroid therapy in critically ill patients with COVID-19: A multicenter retrospective study

Clinical efficacy of glucocorticoids on the treatment of patients with COVID-19 pneumonia: A single center experience

Corticosteroid therapy for patients with severe novel Coronavirus disease 2019

Corticosteroid treatment has no effect on hospital mortality in COVID-19 patients

Systematic corticosteroids and mortality in severe and critical COVID-19 patients in Wuhan

Risk factors for severity and mortality in adult COVID-19 in-patients in Wuhan

Early use of corticosteroid may prolong SARS-CoV-2 shedding in non-intensive care patients with COVID-19 pneumonia: A multicenter-single, blind

High-dose methylprednisolone in nonintubated patients with severe COVID-19 pneumonia

Corticosteroid treatment of patients with coronavirus disease 2019 (COVID-19)

Corticosteroid prevents COVID-19 progression within its therapeutic window: A multicenter proof-of-concept observational study

Effects of corticosteroid treatment for non-severe COVID-19 pneumonia: A propensity score-based analysis

Efficacy evaluation of early, low-dose, short-term corticosteroids in adults hospitalized with non-severe COVID-19 pneumonia: A retrospective cohort study

Corticosteroid use in the treatment of COVID-19: A multicenter retrospective study in Hunan

High dose but not low dose corticoids potentially delay viral shedding of patients with COVID-19

Short term use of oral corticosteroids and related harms among adults in the United States: Population based cohort study

Low-dose corticosteroid therapy does not delay viral clearance in patients with COVID-19

Pharmacologic treatments for coronavirus disease 2019 (COVID-19): A review

Glucocorticoid receptor control of transcription:precision and plasticity via allostery

Antiinflammatory action of glucocorticoids-New mechanisms for old drugs

Cytokine storm induced by SARS-CoV-2

Infection risk and safety of corticosteroid use

The anti-inflammatory and immunosuppressive effects of glucocorticoids, recent developments and mechanistic insights

Dexamethasone induces omega3-derived immunoresolvents driving resolution of allergic airway inflammation

Pro-resolving lipid mediators are leads for resolution physiology

Systematic review on the effect of glucocorticoid use on procoagulant, anti-coagulant and fibrinolytic factors

15-day mortality and associated risk factors for hospitalized patients with COVID-19 in Wuhan, China: An ambispective observational cohort study

Relative immunosuppressive potency of therapeutic corticosteroids measured by whole blood lymphocyte proliferation

Effects of representative glucocorticoids on TNFα-and CD40L-induced NF-κ activation in sensor cells

COVID-19 Treatment guidelines

COVID-19 Illness in native and immunosuppressed states: A clinical-therapeutic staging proposal

Dexamethasone in ARDS Network. Dexamethasone treatment for the acute respiratory distress syndrome: A multicentre, randomised controlled trial

Molecular determinants of vascular transport of dexamethasone in COVID-19 therapy

Weight-based dosing in medication use: What should we know?

Critical COVID-19 disease, homeostasis and the "surprise" of effective glucocorticoid therapy

General adaptation in critical illness: Glucocorticoid receptor-alpha, master regulator of homeostatic corrections

Corticosteroids in COVID-19: One size does not fit all

Factors associated with prolonged viral RNA shedding in patients with coronavirus disease 2019 (COVID-19)

Clinical characteristics and factors accociated with long-term viral excretion in patients with severe acute respiratory syndrome Coronavirus infection: A single-center 28-day study

Association between oral corticosteroid bursts and severe adverse events. A nation population-based cohort study

COVID19 increased the risk of ICU-acquired bloodstream infections: A case-cohort study from the multicentric OUTCOMEREA network

Bloodstream infections in critically ill patients with COVID-19

Invasive pulmonary aspergillosis in nonimmunocompromised hosts

Confronting and mitigating the risk of COVID-19 associated pulmonary aspergillosis

The double-edged sword of systemic cosrticosteroid therapy in viral pneumonia: A case report and comparative review of influenza-associated mucormycosis versus COVID-19 associated mucormycosis

Inhaled corticosteroids and risk of upper respiratory tract infection in patients with asthma: A meta-analysis

Long-term use of inhaled corticosteroids and risk of upper respiratory tract infection in chronic obstructive pulmonary disease: A meta-analysis

Inhaled corticosteroids for stable chronic obstructive pulmonary disease. Cochrane Database Syst

Long-term effects of inhaled corticosteroids on sputum bacterial and viral loads in COPD

The inhaled corticosteroid ciclesonide blocks coronavirus RNA replication by targeting viral NSP15

Identification of antiviral drug candidates against SARS-CoV-2 from FDA-approved drugs

Therapeutic potential of ciclesonide inahalation for COVID-19 pneumonia: Report of three cases

Inhibitory effects of glycopyrronium, formoterol, and budesonide on coronavirus HCoV-229E replication and cytokine production by primary cultures of human nasal and tracheal epithelial cells

Inhaled budesonide in the treatment of early COVID-19 (STOIC): A phase 2, open-label randomized controlled trial

Inhaled corticosteroids and COVID-19: A systematic review and clinical perspective

Global Initiative for Asthma. Global Strategy for Asthma Management and Prevention

Global Strategy for the Diagnosis, Management, and Prevention of Chronic Obstructive Pulmonary Disease. 2020. Available online: www.goldcopd.org

Funding: This research received no external funding.

Data Availability Statement: Not applicable.

The authors declare no conflict of interest.