Corticosteroid Therapy in Pulmonary Sequelae of Covid-19 (COPOSTCOVID)

The first case of the new coronavirus (SARS-CoV-2) was recorded in Wuhan, China.

A virus with a high capacity for dissemination, after 4 months, there were already 200,000 deaths caused by COVID-19 worldwide, and high incidence has a high lethality rate.

Up to 20% of affected patients require hospitalization and oxygen therapy, more than 5% of those affected will require intensive care and orotracheal intubation or critical cases, and 2 to 3% will die regardless of the treatment instituted.

The coronavirus infects human cells by binding to the angiotensin-converting enzyme 2 (ACE2) receptor, a receptor present in cells of the lung, heart, kidney, and intestinal tissue (WU et al., 2020).

In lung tissue, it causes damage to the alveolar epithelium, which directly impacts the reduction of the gas exchange area, leading to a decrease in the diffusion capacity of oxygen and carbon dioxide. After the acute phase of the injury, the repair phase of the damaged tissue begins, and the gas exchange area improves, in most cases, enough for the patient to be removed from mechanical ventilation, but there will be extensive lung injury that is still in the recovery phase. At the time, lung tissue injury with characteristics of DAD was already evident, with the presence of multinucleated pneumocytes, which are secondary to the aggression of these cells and proliferation of intrabronchial fibro granular tissue (similar to organizing pneumonia or bronchiolitis obliterans - BOOP) (TSE et al., 2004), evidencing lymphocytic alveolitis, acute fibrinoid injury, and organizing pneumonia (REMMELINK et al., 2020).

In fatal forms, there is DAD with deposition of fibrinous exudate, formation of hyaline membrane, hyperplasia and loss of type 2 pneumocytes, loss of continuity of the basement membrane, and thickening of the alveolar tissue (WIGÉN et al., 2020).

Some people are more susceptible to developing the severe form of coronavirus, such as men, the elderly, diabetics, and obese people. The justification for the worse evolution of the clinical picture for some groups to the detriment of others is that for predisposed people, the severe form of coronavirus has a weaker innate and adaptive response to the action of the virus, which would explain why children and women are less susceptible to the severe pulmonary form (WIGÉN et al., 2020).

After acute lung injury, a process of repair of the alveolar structures begins with stem cells present in the tissue itself. Alveolar macrophages phagocytose the injured tissue, produce cytokines and growth factors involved in tissue repair, and stimulate the differentiation of these cells for the formation of new tissue and deposition of connective tissue. Injury to the pulmonary epithelium and endothelium occurs in the inflammatory phase of COVID-19, as there is dysregulation in the matrix of metalloproteinases (MO et al., 2020)(RAI; SHARMA; KUMAR, 2020). However, when extensive lung injury occurs and the deposition of excess connective tissue and migration of fibroblasts that become myofibroblasts forming fibrotic tissue (OJO et al., 2020). What remains unknown is why certain individuals develop sequelae due to the accumulation of myofibroblasts and excessive collagen deposition, while others recover quickly and completely (RAI; SHARMA; KUMAR, 2020).

The risk factors for the development of persistent interstitial lung disease are related to the greater severity of the disease and are older age, greater severity of lung involvement, increased lactic dehydrogenase (LDH) secondary to the extent of damage to lung tissue in the acute phase of the disease, stay in the intensive care unit, time of orotracheal intubation, smoking and alcoholism (OJO et al., 2020).

Another factor related to the severity of the condition is lymphopenia. The measurement taken at the beginning of the condition predicts a risk of greater lung damage and worse lung recovery since the reduction in lymphocytes causes a deficiency in viral clearance and greater damage to the organism (WIGÉN et al., 2020). The urea level at the beginning of the condition is also related to the aggressiveness of the kidney injury and predicts a worse lung prognosis.

The possible mechanism that would explain persistent lung injuries is that the virus when binding to angiotensin-converting enzyme 2 (ACE2) receptors, internalizes the receptor, and thus, the virus gains access to the cell and begins to attack the organism. Due to downregulation, there is a reduction in the expression of the ACE2 receptor. However, this receptor is part of the renin-angiotensin system, which plays an important role in regulating the immune response and in the recovery of damaged tissue (WIGÉN et al., 2020). Thus, the process of regulating the inflammatory response and recovering lung tissue is impaired, which allows for greater aggression to the lung parenchyma.

There are some differences between the lung disease caused by the new coronavirus and other forms of acute respiratory distress syndrome (ARDS), despite the intense aggression, with lung involvement being the main predictor of severity and sequelae of all of them. COVID-19 has a peculiarity: it causes alveolar damage with low elastance, while others have high elastance. In addition, the computed tomography findings are different from the classic findings of ARDS due to other etiologies, and altered coagulation is also a finding exclusive to COVID-19. In addition to these typical characteristics, residual interstitial lung disease in COVID-19 is different from other fibrosing diseases, such as idiopathic pulmonary fibrosis and fibrosing interstitial lung diseases, as they are mainly marked by the involvement of the pulmonary endothelium, while COVID-19 is marked by the involvement of the alveolar epithelium (RAI; SHARMA; KUMAR, 2020).

Recovery from the pulmonary condition is a slow process, and patients remain symptomatic for a long period, with dyspnea being a very common symptom. Patients who recover, including those with mild symptoms, maintain fatigue in 53% of cases, dyspnea on exertion in 43%, and chest pain in 21.7%, showing that there is a functional pulmonary sequelae in patients who have recovered from COVID-19 (CARFÌ; BERNABEI; LANDI, 2020).

Functional tests to assess possible pulmonary sequelae show that even mild cases can have diffusion changes, and as the severity of the disease increases, the change becomes greater. Functional tests capable of detecting changes are the measurement of carbon monoxide diffusion (DLCO), with an average reduction of 47%, and total lung capacity, with a reduction of 25% after the end of symptoms. These data are even worse in more severe patients (MO et al., 2020), (NUSAIR, 2020). In a 3-month follow-up after hospital discharge, up to 25% of patients maintain diffusion changes (HUANG et al., 2021). Another follow-up study, after 3 months of hospital discharge, showed that up to 25% of patients maintain spirometric changes. And, 9 out of 55 people evaluated (16.3%), even with mild symptoms of the disease in the acute phase, maintained diffusion changes (ZHAO et al., 2020).

Chest computed tomography is the exam that defines the severity of aggression against the lung parenchyma in a quantitative way. Extensive lesions, interstitial thickening, ground-glass opacities, irregular interface, thick reticular pattern, and parenchymal bands predict a greater degree of progression to residual interstitial lung disease.

A study that evaluated lung lesions in the short term after hospital discharge, with serial tomography scans, showed that there was an improvement in lung lesions in 4 weeks in up to 64.7% of patients (consolidations from 49% to 2%, focal ground-glass opacities from 17.7% to 9.8%, multiple ground-glass opacities from 80.4% to 23.5%, interlobular septal thickening from 80.4% to 35.3%, subpleural lines from 29.4% to 7.8%, irregular lines from 41.2% to 15.7%) and disappeared completely in 25.5% of patients (LIU et al., 2020). This shows that most of the changes are inflammatory and largely recover after one month of hospital discharge. However, persistent lesions can progress to persistent interstitial lung disease.

Research project, June 23, 2021 In another study, in patients who required mechanical ventilation, follow-up after 3 months showed complete recovery of lung lesions in only 2 of the 41 patients evaluated. In this study, 89% of patients still had ground-glass opacities according to computed tomography (CT), signs of reticulation and fibrotic bands, with and without parenchymal distortion, bronchiectasis and bronchiolectasis in up to 67% of cases, presence of emphysematous destruction or cavities, with worsening and of pre-existing emphysema. Some patients presented areas of air retention, but this was not a frequent finding, and traction bronchiectasis was rare. This study showed that pulmonary sequelae in patients who had extensive lung involvement are very common and can progress to permanent interstitial lung disease. Also, most people who required mechanical ventilation had changes in lung function and residual changes visualized on high-resolution CT (HRCT) (VAN GASSEL et al., 2021).

The evaluation after 6 months of hospital discharge of patients with COVID-19 showed persistent pulmonary changes on CT in 52% of individuals who did not require oxygen support and 54% of those who required mechanical ventilation, noninvasive ventilation, or other ventilatory support. Regarding DLCO, even patients with the mild form of the disease may maintain alterations, present in 22% of patients who did not require oxygen therapy and in 56% of patients who required some type of ventilatory support (HUANG et al., 2021).

The treatment of the pulmonary condition still in the acute phase in patients requiring orotracheal intubation and oxygen therapy (DE BACKER; AZOULAY; VINCENT, 2020) demonstrated benefit with immunosuppressive doses of corticosteroid therapy due to a pattern of injury to the lung tissue with lymphocytic alveolitis, acute fibrinoid injury and organizing pneumonia (REMMELINK et al., 2020), all of which are acute alterations responsive to corticosteroid therapy.

In hospitalized patients, the use of corticosteroid therapy with dexamethasone and methylprednisolone has the potential to reduce mortality. Furthermore, the comparison between the two types of corticosteroids showed that the use of methylprednisolone was more effective (KO et al., 2021).

After the recovery period, interstitial lung disease persists in many patients, but the lesions are not characteristic of definitive fibrosis with honeycombing. According to RAI et al., 2020 (RAI; SHARMA; KUMAR, 2020), the studies reviewed in the literature designated the pulmonary sequelae as pulmonary fibrosis. However, in a recent study, it was called persistent interstitial lung involvement due to the lack of definitive characteristics of a fibrosing lesion and the presence of possible reversible lesions (WELLS; DEVARAJ; DESAI, 2021).

The evaluation time to confirm persistent lung disease and the period of natural recovery from the disease are still uncertain. However, data from the literature on the follow-up of severe pneumonia show that the radiological recovery time should be around six weeks. Regarding MERS and SARS-CoV-1, the radiological recovery time is around 12 weeks, with complete resolution of radiological alterations in two-thirds of patients during this period, and the maintenance of radiological alterations after this period indicates a high probability of permanent lung disease (GEORGE et al., 2020). This review also suggests a post-COVID-19 follow-up after 12 weeks with chest X-ray, diffusion measurements, and walk test to assess desaturation during exertion, and if any alteration is identified, a chest HRCT scan is considered to assess interstitial lung disease. However, the initial assessment or screening performed only with a simple chest X-ray may lead to the non-identification of pulmonary sequelae due to its low sensitivity.

Follow-up of patients after 6 months of hospital discharge showed changes in chest X-rays in up to 25% of patients and reduced diffusion in 46%, but only 31% of patients had dyspnea on exertion with MMRC greater than or equal to 1 (FAVERIO et al., 2021), the most severe patients are those with greater impairment in diffusion capacity and changes in imaging tests (HUANG et al., 2021).

Studies on which treatment would be most effective for persistent interstitial disease have not yet been established in the medical literature, and the medications currently being tested are nintedanib, pirfenidone, chloroquine, and corticosteroids. Prophylactic measures such as protective mechanical ventilation techniques, measures to prevent pneumonia infections and other respiratory complications can reduce the risk of residual lung disease (RAI; SHARMA; KUMAR, 2020).

A study on the use of corticosteroids in patients with pulmonary sequelae showed significant improvement after the use of a dose of 0.5 mg/kg, but with rapid weaning and weaning beginning in the first week of use. This study did not have a control group, and patients were followed for 3 months only after inclusion and initiation of treatment (MYALL et al., 2021). The use of corticosteroids plays a crucial role in the treatment of inflammatory lung disease related to COVID-19, apparently in all phases of the disease.

Since COVID-19-related lung lesions in the acute phase are responsive to corticosteroid therapy, it is inferred that, for persistent interstitial lung disease that demonstrates an inflammatory pattern with alveolar involvement, corticosteroid therapy may also have an important role. There are no controlled and randomized studies on any treatment and its effect on the natural history of this complication of COVID-19.