Tuberc Respir Dis > Volume 84(3); 2021 > Article
Lee, Park, Lee, Park, and Heo: The Effect of the Timing of Dexamethasone Administration in Patients with COVID-19 Pneumonia

Abstract

Background

Despite the proven benefits of dexamethasone in hospitalized coronavirus disease 2019 (COVID-19) patients, the optimum time for the administration of dexamethasone is unknown. We investigated the progression of COVID-19 pneumonia based on the timing of dexamethasone administration.

Methods

A single-center, retrospective cohort study based on medical record reviews was conducted between June 10 and September 21, 2020. We compared the risk of severe COVID-19, defined as the use of a high-flow nasal cannula or a mechanical ventilator, between groups that received dexamethasone either within 24 hours of hypoxemia (early dexamethasone group) or 24 hours after hypoxemia (late dexamethasone group). Hypoxemia was defined as room-air SpO2 <90%.

Results

Among 59 patients treated with dexamethasone for COVID-19 pneumonia, 30 were in the early dexamethasone group and 29 were in the late dexamethasone group. There was no significant difference in baseline characteristics, the time interval from symptom onset to diagnosis or hospitalization, or the use of antiviral or antibacterial agents between the two groups. The early dexamethasone group showed a significantly lower rate of severe COVID-19 compared to the control group (75.9% vs. 40.0%, p=0.012). Further, the early dexamethasone group showed a significantly shorter total duration of oxygen supplementation (10.45 days vs. 21.61 days, p=0.003) and length of stay in the hospital (19.76 days vs. 27.21 days, p=0.013). However, extracorporeal membrane oxygenation and in-hospital mortality rates were not significantly different between the two groups.

Conclusion

Early administration of dexamethasone may prevent the progression of COVID-19 to a severe disease, without increased mortality.

Introduction

Systemic administration of corticosteroids has been associated with decreased in-hospital mortality in coronavirus disease 2019 (COVID-19) patients with hypoxemia1. Among systemic corticosteroids, dexamethasone has been demonstrated to improve mortality in COVID-19 patients in two randomized controlled trials (RCTs)2,3, but the benefit of hydrocortisone or methylprednisolone is not as clear1,4,5. However, 36.2% (166/459) of patients who used dexamethasone eventually died1, suggesting that dexamethasone should be used in a timely manner only in selective patients6. Nevertheless, there is little information concerning the prognosis for COVID-19 patients that relates to different times of dexamethasone administration.
The efficacy of dexamethasone in protecting against acute respiratory distress syndrome (ARDS) is likely to be related to the time of initial drug administration. A recent RCT showed that dexamethasone administration within 30 hours of ARDS onset decreased the duration of mechanical ventilation and mortality rates7. COVID-19 studies also showed a potential benefit of early dexamethasone treatment in improving the prognosis in patients with acute respiratory failure. In the Co-DEX trial, dexamethasone administration within 48 hours of the onset of ARDS significantly increased ventilator-free days in the COVID-19 patients3. A quasi-experimental study of moderate-to-severe COVID-19 cases found that systemic corticosteroid administered from the first day of oxygen supplementation reduced a composite of primary outcomes, including intensive care unit care, progression to respiratory failure, and in-hospital mortality8. In addition, there was a positive correlation between early corticosteroid treatment and a better clinical prognosis in severe acute respiratory syndrome9.
The timing of dexamethasone administration is of special concern in those COVID-19 patients who need only oxygen therapy. This study determined whether there is a difference in the rate of ARDS progression, based on the time of dexamethasone administration, in COVID-19 patients who needed only oxygen therapy without either high-flow nasal cannula (HFNC) therapy or a mechanical ventilator (MV).

Materials and Methods

Our study was reported in accordance with the guidelines of the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) statement10.

1. Study design and participants

The present retrospective cohort study included all the hospitalized patients who received dexamethasone for COVID-19 pneumonia at Seoul Metropolitan Government-Seoul National University Boramae Medical Center (SMG-SNU BMC), Seoul, between June 10 and September 21, 2020. A diagnosis of COVID-19 was confirmed through quantitative reverse transcription-polymerase chain reaction (RT-qPCR) assays using upper or lower respiratory tract samples.
Patients were admitted to the isolation ward for COVID-19 management, which has negative pressure ventilation. Dexamethasone was administrated to the COVID-19 patients who required oxygen therapy or had a significant desaturation (a change in pulse oximeter oxygen saturation [SpO2] >4%) with clinical signs of aggravated pneumonia. The time of dexamethasone administration was determined by the attending physician. Oxygen supplementation was initiated when patients had a room-air SpO2 <90%, which is defined as hypoxemia. Oxygen saturation was monitored through pulse oximetry for 24 hours during oxygen supplementation. Administration of remdesivir was allowed in the patients who met all of the following criteria: (1) pneumonic infiltration was evident in a chest X-ray or chest computed tomography (CT) scan, (2) room-air SpO2 <94%, (3) oxygen supplementation, and (4) ≤10 days since symptom onset. In practice, remdesivir was administered only to patients over 70 years of age because of the limited supply of remdesivir during the study period. Administration of antibiotics for respiratory infections was also allowed when a bacterial infection had not been ruled out.

2. Eligibility criteria

The eligibility criteria were as follows: (1) age >18 years old, (2) detection of severe acute respiratory syndrome coronavirus 2 by an RT-qPCR assay of upper or lower respiratory sample, (3) evidence of pneumonia in a chest X-ray or chest CT scan, and (4) administration of dexamethasone before initiation of HFNC treatment or a MV. Exclusion criteria were immunosuppressive diseases, treatment with a systemic corticosteroid or other immunosuppressive drugs, pregnancy, terminal-stage cancer, or other end-stage diseases.

3. Variables and measurements

Demographic information for the study population was collected, including age, sex, body mass index, smoking status, Charlson comorbidity index (CCI), and underlying diseases (hypertension, diabetes, cerebrovascular disease, cardiovascular disease, chronic lung disease, chronic kidney disease, chronic liver disease, and cancer). Symptoms of COVID-19 were determined by medical staff when dexamethasone treatment was initiated, including abnormal senses of smell or taste, myalgia, sore throat, cough, sputum, chest discomfort, dyspnea, fever or chills, rhinorrhea, and nausea or diarrhea. Ct-values of RT-qPCR at first diagnosis were obtained. Clinical severity was evaluated using the Sequential Organ Failure Assessment (SOFA) score and the Simplified Acute Physiology Score (SAPS) II, SpO2, and PaO2/FiO2 ratio (ratio of arterial partial pressure of oxygen to fraction of inspired oxygen) at hypoxemia development. Laboratory tests included assays for white blood cells, lymphocytes, C-reactive protein, procalcitonin, lactate dehydrogenase, troponin-I, and D-dimer. Treatment information included the use of antiviral or antibacterial agents, total dose of dexamethasone, duration of dexamethasone treatment, the time interval from symptom onset or diagnosis to initiation of dexamethasone administration, and the time interval from hypoxemia to dexamethasone administration.

4. Study groups and outcomes

We defined the initiation time of dexamethasone treatment as the time interval from occurrence of hypoxemia to initiation of dexamethasone treatment. The distribution of the initiation time of dexamethasone was largely divided into two groups based on the criteria of 24 hours in a pilot analysis. The patients with the initiation time of dexamethasone treatment <24 hours were defined as early dexamethasone group and those ≥24 hours were defined as late dexamethasone group. The primary outcome was to compare the rate of HFNC or MV treatments between early and late dexamethasone group. HFNC was used when oxygen supplementation with nasal prong 6 L/min or more was required. The secondary outcome was to compare the total duration of oxygen supplementation and the length of stay in hospital for the two groups.

5. Statistical analyses

Demographic information, symptoms, clinical features, clinical severity, and study outcomes were compared between the early and late dexamethasone groups. We conducted Shapiro-Wilk normality test for each continuous variable before statistical tests. Categorical variables were analyzed with Pearson’s chi-square test or the Fisher exact test. Continuous variables were analyzed with the Student’s t test or Mann-Whitney U test. Repeated measure analysis of variance was conducted for analysis of serial physiologic parameters (respiratory rate, heart rate, and SpO2) and laboratory results (complete blood count). Logistic regression analysis was used to determine whether the timing of dexamethasone administration correlated with HFNC or MV treatments by calculating odds ratios and 95% confidence intervals (CIs). To exclude potential bias due to confounding factors associated with the use of HFNC or MV treatments, we conducted a multivariate analysis. Independent variables were selected on the basis of their statistical significance in the univariate analysis. The criterion for inclusion of a variable in the multivariate analysis was based on the clinical significance. The Kaplan-Meier curve was used to visualize the difference in the time to HFNC or MV treatment between the early and late dexamethasone groups, and the statistical significance was estimated by the log-rank test. Univariable and multivariable Cox regression analyses were used to evaluate hazard ratios (HRs) for prolonged time to HFNC or MV treatments. Multivariable analyses were conducted using two models. In model 1, early dexamethasone group was used as a categorical variable for multivariable analysis. In model 2, initiation time of dexamethasone treatment was used as a continuous variable for multivariable analysis. We considered p-values <0.05 as statistically significant. All the statistical analyses were conducted using R statistical software (version 3.5.1, 2018, R Core Team, Vienna, Austria).

6. Ethics

The Institutional Review Board Committee of Seoul National University Seoul Metropolitan Government (SNUSMG) Boramae Medical Center approved the study protocol and waived the need for informed consent for access to the electronic medical records (IRB No. 20-2020-33).

Results

Among a total of 212 patients hospitalized for treatment of COVID-19, 62 (29.2%) were treated with dexamethasone. After excluding three patients who received dexamethasone after HFNC treatment, 59 patients (27.8%) were placed in two groups: an early dexamethasone group (30 patients) and a late dexamethasone group (29 patients) (Figure 1). Time interval from hypoxemia to dexamethasone administration was median 0 day (interquartile range [IQR], 0-0) in early dexamethasone group and median 2 days (IQR, 1-2) in late dexamethasone group. The time interval from symptom onset to diagnosis of COVID-19 was a median 3.0 days (IQR, 0-5.0). The median time interval from symptom onset to hospitalization for COVID-19 was 3.0 days (IQR, 1.0-6.5). All the patients showed evidence of pneumonic infiltration in the initial chest X-ray at admission.

1. Baseline characteristics and clinical features of the study population

In baseline characteristics, age, percentage of current smokers, and CCI were higher in the late dexamethasone group, but the values were not statistically significant (Table 1). The frequency of each symptom was not significantly different between the early and late dexamethasone groups.
In terms of clinical features, early dexamethasone group showed a higher SOFA score and SAPS II at hypoxemia development (Table 2). PaO2/FiO2 ratio was lower in the early dexamethasone group. While heart rate serially decreased, SpO2, applied oxygen flow rate, white blood cells, and platelet were increased during initial 3 days after dexamethasone administration (Supplementary Table S1). In terms of treatments, the rate of remdesivir use or antibiotic use was very similar in the early and late dexamethasone groups. The dose of dexamethasone and the duration of dexamethasone treatment were similar between the two groups. Two patients in the early dexamethasone group started dexamethasone 1.5 (±0.7) days before oxygen supplementation because they showed imminent hypoxemic respiratory failure with fever, a progression of pneumonic infiltration, and decreasing SpO2.

2. Association between clinical outcomes and the time of dexamethasone administration

Twelve patients (40.0%) in the early dexamethasone group and 22 patients (75.9%) in the late dexamethasone group required HFNC or MV treatment, which was significantly different between the two groups (p=0.012) (Table 2). MV was applied to seven patients (23.3%) in early dexamethasone group and 13 patients (44.8%) in late dexamethasone group (p=0.142). Two patients in the late dexamethasone group were given extracorporeal membrane oxygenation (ECMO) and there was no difference in ECMO use between the two groups. The early dexamethasone group showed a significantly shorter duration of oxygen supplementation (10.45 days vs. 21.61 days, p=0.003) and length of stay in hospital (19.76 days vs. 27.21 days, p=0.013). We found no difference in in-hospital deaths between the two groups, which were caused in both groups by respiratory failure.
In the Kaplan-Meir estimate, the probability of HFNC or MV treatment was significantly lower in the early dexamethasone group (log-rank test=0.002) (Figure 2). Univariable Cox regression analysis revealed that the probability of HFNC or MV treatment was significantly lower over time in the early dexamethasone group (HR, 0.344 [95% CI, 0.169-0.698]; p=0.003) (Table 3). However, initiation time of dexamethasone treatment was not significantly associated with the probability of HFNC or MV treatment. In the multivariable Cox regression analysis, the probability of HFNC or MV treatment was significantly lower in the early dexamethasone group (HR, 0.440 [95% CI, 0.211-0.915]; p=0.028; model 1), but not significantly related with initiation time of dexamethasone treatment (model 2).

Discussion

Our study identified a correlation between the administration of dexamethasone within 24 hours of oxygen supplementation (early dexamethasone) and a lower rate of HFNC or MV treatment in COVID-19 patients who required oxygen therapy or had a significant desaturation. In addition, the early dexamethasone group showed a significantly shorter total duration of oxygen supplementation and length of stay in hospital. Early dexamethasone treatment was significantly correlated with a lower rate of HFNC or MV treatment, even in multivariable Cox regression analysis. However, the probability of HFNC or MV treatment was not associated with the initiation time of dexamethasone in Cox regression analyses, which finding suggests that the risk of HFNC or MV treatment was not linearly increased as the initiation time of dexamethasone was prolonged. Although the early dexamethasone group required less HFNC or MV treatment, there was no difference in ECMO use or in-hospital mortality rates between the early and late dexamethasone groups. Therefore, early dexamethasone administration for hypoxemic COVID-19 patients may reduce the need for HFNC or MV treatment without increased mortality; thus, reducing the need for scarce medical resources in the COVID-19 pandemic11.
Although we know that dexamethasone is associated with a lower mortality rate in COVID-19 patients undergoing oxygen therapy alone2, information is needed about when dexamethasone treatment should be initiated to maximize the benefits. Considering the evidence to date, the administration of corticosteroids seems to be more effective for COVID-19 patients with active progression to ARDS than those with early-phase pneumonia. In the RECOVERY study, dexamethasone reduced more mortality in the invasive MV group (25.2%; rate ratio=0.64 [95% CI, 0.51-0.81]), in which pneumonia was more advanced, than the oxygen-only group (37.5%; rate ratio, 0.82 [95% CI, 0.72-0.94])2. In the CoDEX study, dexamethasone benefited COVID-19 patients who used an MV after ARDS developed3. A recently published meta-analysis showed that dexamethasone benefits a subgroup of patients with symptom onset >7 days1. The mechanism by which dexamethasone reduces the pulmonary and systematic inflammatory process may contribute to these results12.
The progression of COVID-19 pneumonia from mild to severe disease can be characterized by initial mild infection phase followed by pulmonary inflammation phase, and then systemic hyper-inflammation phase13,14. Down-regulation of pulmonary and systemic inflammation is considered one of the most decisive factors for restoration to normal physiology in COVID-19 pneumonia15. Therapeutic strategy for ARDS due to COVID-19 should be based on suppression of pathological inflammation by controlling macrophage activation and cytokine release16. The clinical benefits of glucocorticoid in ARDS have been explained by improved profiles of biologic markers for alveolar-capillary membrane permeability and mediators for inflammation and tissue repair17. In RCTs that proved the efficacy of dexamethasone in ARDS, dexamethasone treatment was initiated in the early phase of ARDS (within 48 hours of onset)3,7. Therefore, we can speculate that early administration of dexamethasone may attenuate the extent of lung injury or systemic organ damage and prevent progression to severe ARDS or systemic cytokine storm.
In our study, the number of patients in the early and late dexamethasone treatment groups was almost the same and two groups were distributed relatively evenly over study period, which reflects the controversy in clinical practice concerning the optimum time for dexamethasone administration. In the late dexamethasone group, it is likely that the physician did not expect the oxygen demand of the patient to increase; thus, dexamethasone would not have been be prescribed immediately. In fact, before studies on mortality reduction by dexamethasone were published, we had COVID-19 pneumonia cases where the oxygen demand gradually decreased without dexamethasone18. However, there is still no good tool to predict whether COVID-19 pneumonia will worsen. Serious adverse events were no different between patients treated or not treated with dexamethasone, while the benefit of dexamethasone was significant only in the oxygen group1,2. In our study, dexamethasone treatment within 24 hours of oxygen supplementation decreased the need for HFNC or MV interventions. The mean time from symptom onset to dexamethasone treatment was about 7.4 days. Therefore, when oxygen supplementation is needed, especially after 7 days of symptom onset, prompt administration of dexamethasone may be advantageous.
The present study has several limitations. First, it should be noted that there is a risk of bias in generalizing our results to all the patients with COVID-19 pneumonia. This study was a single-center retrospective observational study with a small number of patients. Our study population was highly selective by narrow range of inclusion criteria and confounding factors were not controlled. Some differences in baseline condition may not be detected by type II error. Second, the early dexamethasone group may have included more patients with less severe COVID-19 pneumonia, although there was no difference in SOFA scores and SAPS II between the early and late dexamethasone groups. The late dexamethasone group received dexamethasone only after progression of hypoxemia, whereas in the early group dexamethasone was administered as soon as hypoxemia occurred. Therefore, the patients with a milder disease, who improved without dexamethasone, may not have been included in the late dexamethasone group, but would have been included in the early dexamethasone group. Third, our study did not include very severe cases with rapid progression to ARDS. We excluded three patients who had severe hypoxemia at admission and needed HFNC treatment immediately, before dexamethasone was started. Although the anti-inflammatory effect of dexamethasone is likely to be most pronounced in ARDS patients with rapid progression, our results cannot be extrapolated to these patients. Fourth, the early and late dexamethasone groups had similar rates of remdesivir treatment; however, the timing of remdesivir administration was as late as that of dexamethasone in the late dexamethasone group.
In conclusion, the administration of dexamethasone within 24 hours of oxygen supplementation correlated with a lower rate of HFNC or MV treatment in patients with severe COVID-19 pneumonia. The duration of oxygen supplementation and length of hospital stay were shorter in the early dexamethasone treatment group. Early administration of dexamethasone may also be beneficial in the prevention of ARDS progression and may prevent the need for HFNC or MV treatment, without an increase in fatal events.

Supplementary Material

Supplementary material can be found in the journal homepage (http://www.e-trd.org).
Supplementary Table S1. Serial change of physiologic parameters from the time when hypoxemia occurred (day 0) to day 3.
trd-2021-0009-suppl.pdf

Notes

Authors’ Contributions

Conceptualization: Lee HW, Heo EY. Formal analysis: Lee HW, Heo EY. Data curation: Lee HW, Heo EY. Writing - original draft preparation: Lee HW. Writing - review and editing: Park M, Lee JK, Park TY, Heo EY. Approval of final manuscript: all authors.

Conflicts of Interest

No potential conflict of interest relevant to this article was reported.

Funding

No funding to declare.

Figure 1
Flow chart of patient inclusion. SARS-CoV-2: severe acute respiratory syndrome coronavirus 2; PCR: polymerase chain reaction; COVID-19: coronavirus disease 2019; HFNC: high-flow nasal cannula.
trd-2021-0009f1.jpg
Figure 2
Kaplan-Meier curve for probability of high-flow nasal cannula (HFNC) or mechanical ventilator (MV) treatment for 2 weeks after the initiation of dexamethasone administration.
trd-2021-0009f2.jpg
Table 1
Baseline characteristics of COVID-19 patients in early and late dexamethasone groups
Characteristic Late dexamethasone group (n=29) Early dexamethasone group (n=30) p-value
Age, yr 70.07±13.87 65.53±14.39 0.138
Female sex 12 (41.4) 10 (33.3) 0.712
Body mass index 24.32±4.64 24.68±4.33 0.764
Current smoker 5 (17.2) 2 (6.7) 0.394
Charlson comorbidity index 4.34±2.06 3.50±2.35 0.147
Underlying disease
 Hypertension 15 (51.7) 15 (50.0) >0.990
 Diabetes mellitus 10 (34.5) 9 (30.0) 0.928
 Cerebrovascular disease 4 (13.8) 5 (16.7) 1.000
 Cardiovascular disease 7 (24.1) 4 (13.3) 0.465
 Chronic lung disease 5 (17.2) 3 (10.0) 0.666
 Chronic kidney disease 2 (6.9) 5 (16.7) 0.449
 Chronic liver disease 3 (10.3) 3 (10.0) >0.990
 Cancer 5 (17.2) 2 (6.7) 0.394
Symptoms
 Abnormality in sense of smell and taste 2 (6.9) 2 (6.7) >0.990
 Myalgia 12 (41.4) 10 (33.3) 0.712
 Sore throat 3 (10.3) 6 (20.0) 0.503
 Cough 16 (55.2) 13 (43.3) 0.516
 Sputum 12 (41.4) 8 (26.7) 0.358
 Chest discomfort 1 (3.4) 3 (10.0) 0.629
 Dyspnea 18 (62.1) 15 (50.0) 0.502
 Febrile or chilling sense 14 (48.3) 20 (66.7) 0.244
 Rhinorrhea or nasal obstruction 0 (0) 1 (3.3) >0.990
 Gastrointestinal symptoms 4 (13.8) 3 (10.0) 0.962
 No symptoms 3 (10.3) 2 (6.7) 0.968

Values are presented as the mean±standard deviation or number (%).

COVID-19: coronavirus disease 2019.

Table 2
Clinical features and outcomes of COVID-19 patients in early and late dexamethasone groups
Variable Late dexamethasone group (n=29) Early dexamethasone group (n=30) p-value
Clinical features
 Ct-value of RT-PCR at first diagnosis
  E gene 22.07±6.32 21.65±4.92 0.786
  RdRP gene 21.80±6.49 20.36±5.60 0.382
 Clinical severity
  SOFA score at hypoxemia development 3.5±1.8 4.6±2.2 0.044
  SAPS II at hypoxemia development 21.1±6.2 26.7±9.7 0.010
  SpO2 at hypoxemia development 88.9±4.9 87.0±3.1 0.081
  PaO2/FiO2 ratio at hypoxemia development 296±117 202±63 <0.001
 Laboratory test at hypoxemia development
  White blood cell counts, ×103/μL 5,963±3,705 6,490±2,377 0.517
  The number of lymphocytes, ×103/μL 946±376 1,018±499 0.533
  C-reactive protein, mg/dL 7.50±6.34 9.59±6.50 0.217
  Procalcitonin, ng/mL 0.05 (0.04-0.08) 0.09 (0.05-0.21) 0.181
  Lactate dehydrogenase, IU/L 293 (220-376) 367 (303-450) 0.111
  Troponin-I, ng/mL 9.1 (4.2-13.8) 10.2 (5.2-19.2) 0.124
  D-dimer, mg/L 0.8 (0.5-2.1) 0.8 (0.6-1.6) 0.640
 Treatment
  Remdesivir 13 (44.8) 12 (40.0) 0.911
  Antibiotics 29 (100) 30 (100) NA
  Total accumulative dose of dexamethasone mg 62.62±33.34 64.17±32.48 0.857
  Total duration of dexamethasone mg 10.66±5.58 10.57±4.48 0.947
  Time interval from symptom onset to dexamethasone administration, day 7.76±3.59 7.03±3.50 0.435
  Time interval from diagnosis to dexamethasone administration, day 4.14±3.26 4.70±3.67 0.537
  Time interval from hypoxemia to dexamethasone administration, day 2 (1-2) 0 (0-0) <0.001
Clinical outcomes
 High-flow nasal cannula or mechanical ventilation 22 (75.9) 12 (40.0) 0.012
 Extracorporeal membrane oxygenation 2 (6.9) 0 (0) 0.457
 Total duration of oxygen supplementation*,, day 21.61±16.42 10.45±9.39 0.003
 Length of stay in hospital, day 27.21±13.28 19.76±8.05 0.013
 In-hospital death 1 (3.4) 1 (3.3) >0.990

Values are presented as the mean±standard deviation, median (interquartile range), or number (%).

* Oxygen supplementation includes oxygen inhalation through nasal prong, facial mask, high-flow nasal cannula, mechanical ventilator, and extracorporeal membrane oxygenation.

Data regarding total duration of oxygen supplementation and length of stay in hospital were missing for 1 patient in early dexamethasone group and 1 patient in late dexamethasone group.

COVID-19: coronavirus disease 2019; RT-PCR: reverse transcription polymerase chain reaction; SOFA: Sequential Organ Failure Assessment; SAPS: Simplified Acute Physiology Score; SpO2: pulse oximeter oxygen saturation; PaO2/FiO2 ratio: ratio of arterial partial pressure of oxygen to fraction of inspired oxygen.

Table 3
Cox regression analyses to evaluate the probability for high-flow nasal cannula or mechanical ventilation according to time point of dexamethasone administration
Variable Univariable analysis p-value Multivariable analysis (model 1) p-value Multivariable analysis (model 2) p-value
HR 95% CI HR 95% CI HR 95% CI
Age 1.020 0.996-1.045 0.101 - - - - - -
Female sex 0.655 0.319-1.344 0.249 1.142 0.499-2.613 0.753 0.945 0.417-2.144 0.893
Current smoker 2.448 1.009-5.944 0.048 2.071 0.726-5.903 0.173 1.310 0.421-4.073 0.641
Charlson comorbidity index 1.147 0.977-1.347 0.095 1.032 0.850-1.253 0.750 0.976 0.805-1.183 0.803
SOFA score 1.245 1.101-1.409 <0.001 1.182 0.992-1.408 0.062 1.157 0.955-1.402 0.135
SAPS II 1.089 1.049-1.131 <0.001 - - - - - -
No. of lymphocytes at development of hypoxemia 0.999 0.998-1.000 0.036 0.999 0.998-1.000 0.023 0.999 0.998-1.000 0.034
Remdesivir 2.358 1.184-4.695 0.015 1.733 0.847-3.546 0.133 1.544 0.721-3.308 0.264
Early dexamethasone 0.344 0.169-0.698 0.003 0.440 0.211-0.915 0.028 - - -
Initiation time of dexamethasone treatment 1.139 0.902-1.439 0.275 - - - 1.180 0.880-1.582 0.268

Values are presented as the odds ratio and 95% confidence interval.

In model 1, early dexamethasone (initiation time of dexamethasone treatment within 24 hours) was used as a categorical variable for multivariable analysis. In model 2, initiation time of dexamethasone treatment was used as a continuous variable for multivariable analysis. multivariable dox regression analysis was adjusted by covariates including SOFA score and SAPS II.

Age and SAPS II are not included in multivariable analysis due to multicollinearity (variance inflation factor >4).

HR: hazard ratio; CI: confidence interval; SOFA: Sequential Organ Failure Assessment; SAPS: Simplified Acute Physiology Score.

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