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Different durations of corticosteroid therapy for exacerbations of chronic obstructive pulmonary disease

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Background

Current guidelines recommend that patients with acute exacerbations of chronic obstructive pulmonary disease (COPD) should be treated with systemic corticosteroid for seven to 14 days. Intermittent systemic corticosteroid use is cumulatively associated with adverse effects such as osteoporosis, hyperglycaemia and muscle weakness. Shorter treatment could reduce adverse effects.

Objectives

To compare the efficacy of short‐duration (seven or fewer days) and conventional longer‐duration (longer than seven days) systemic corticosteroid treatment of adults with acute exacerbations of COPD.

Search methods

Searches were carried out using the Cochrane Airways Group Specialised Register of Trials, MEDLINE and CENTRAL (Cochrane Central Register of Controlled Trials) and ongoing trials registers up to March 2017.

Selection criteria

Randomised controlled trials comparing different durations of systemic corticosteroid defined as short (i.e. seven or fewer days) or longer (i.e. longer than seven days). Other interventions—bronchodilators and antibiotics—were standardised. Studies with participants requiring assisted ventilation were excluded.

Data collection and analysis

We used standard methodological procedures as expected by The Cochrane Collaboration.

Main results

Eight studies with 582 participants met the inclusion criteria, of which five studies conducted in hospitals with 519 participants (range 28 to 296) contributed to the meta‐analysis. Mean ages of study participants were 65 to 73 years, the proportion of male participants varied (58% to 84%) and COPD was classified as severe or very severe. Corticosteroid treatment was given at equivalent daily doses for three to seven days for short‐duration treatment and for 10 to 15 days for longer‐duration treatment. Five studies administered oral prednisolone (30 mg in four, tapered in one), and two studies provided intravenous corticosteroid treatment. Studies contributing to the meta‐analysis were at low risk of selection, performance, detection and attrition bias. In four studies we did not find a difference in risk of treatment failure between short‐duration and longer‐duration systemic corticosteroid treatment (n = 457; odds ratio (OR) 0.72, 95% confidence interval (CI) 0.36 to 1.46)), which was equivalent to 22 fewer per 1000 for short‐duration treatment (95% CI 51 fewer to 34 more). No difference in risk of relapse (a new event) was observed between short‐duration and longer‐duration systemic corticosteroid treatment (n = 457; OR 1.04, 95% CI 0.70 to 1.56), which was equivalent to nine fewer per 1000 for short‐duration treatment (95% CI 68 fewer to 100 more). Time to the next COPD exacerbation did not differ in one large study that was powered to detect non‐inferiority and compared five days versus 14 days of systemic corticosteroid treatment (n = 311; hazard ratio 0.95, 95% CI 0.66 to 1.37). In five studies no difference in the likelihood of an adverse event was found between short‐duration and longer‐duration systemic corticosteroid treatment (n = 503; OR 0.89, 95% CI 0.46 to 1.69, or nine fewer per 1000 (95% CI 44 fewer to 51 more)). Length of hospital stay (n = 421; mean difference (MD) ‐0.61 days, 95% CI ‐1.51 to 0.28) and lung function at the end of treatment (n = 185; MD FEV1 ‐0.04 L; 95% CI ‐0.19 to 0.10) did not differ between short‐duration and longer‐duration treatment.

Authors' conclusions

Information from a new large study has increased our confidence that five days of oral corticosteroids is likely to be sufficient for treatment of adults with acute exacerbations of COPD, and this review suggests that the likelihood is low that shorter courses of systemic corticosteroids (of around five days) lead to worse outcomes than are seen with longer (10 to 14 days) courses. We graded most available evidence as moderate in quality because of imprecision; further research may have an important impact on our confidence in the estimates of effect or may change the estimates. The studies in this review did not include people with mild or moderate COPD; further studies comparing short‐duration systemic corticosteroid versus conventional longer‐duration systemic corticosteroid for treatment of adults with acute exacerbations of COPD are required.

PICOs

Population
Intervention
Comparison
Outcome

The PICO model is widely used and taught in evidence-based health care as a strategy for formulating questions and search strategies and for characterizing clinical studies or meta-analyses. PICO stands for four different potential components of a clinical question: Patient, Population or Problem; Intervention; Comparison; Outcome.

See more on using PICO in the Cochrane Handbook.

Are shorter courses of systemic steroids as effective as conventional longer courses in the treatment of patients with flare‐ups of COPD?

Why is this question important?

Chronic obstructive pulmonary disease (COPD), which includes emphysema and chronic bronchitis, is a long‐term lung condition that is commonly associated with smoking. Patients with COPD may experience flare‐ups (exacerbations), often precipitated by infection, in which symptoms such as breathlessness, cough and phlegm become markedly worse, and extra treatment or admission to hospital is required.

Systemic (i.e. not inhaled) corticosteroids, such as prednisolone, prednisone and cortisone, are commonly used in the treatment of patients with these flare‐ups (exacerbations). We wanted to assess whether a shorter course (seven or fewer days) of this treatment was as good as a course of usual length (longer than seven days) and caused fewer side effects.

How did we answer the question?

We looked for all studies that compared oral or injected corticosteroid treatment given for seven or fewer days versus treatment given for longer than seven days in people with acute exacerbations of COPD.

What did we find?

We found eight studies that included 582 people with COPD who experienced a flare‐up that required extra treatment in hospital. These studies compared oral or injected corticosteroid treatment given for seven or fewer days versus treatment for longer than seven days. Most of the people in these studies were in their late sixties and had severe or very severe symptoms of COPD; more men than women took part. The last search for studies to be included in the review was conducted in March 2017.

No differences were observed between shorter and longer courses of treatment. People treated for seven or fewer days did not have a higher rate of treatment failure or longer time to their next exacerbation; the number of people who avoided treatment failure ranged from 51 fewer to 34 more per 1000 treated (average 22 fewer people per 1000). Time in hospital and lung function (blowing tests) at the end of treatment were not different. No differences in side effects or death were noted between treatments. Information on quality of life, which is an important outcome for people with COPD, is limited, as only one study measured it.

The eight studies included in this review were generally well designed, and the quality of the evidence was rated as moderate because of imprecision in results; more research, especially involving people with less severe COPD, is needed.

Authors' conclusions

Implications for practice

We have obtained information from one new large study that has increased our confidence that five days of oral corticosteroids is likely to be sufficient for treatment of patients with exacerbations of COPD, and this review suggests that the likelihood that shorter courses of systemic corticosteroids (of around five days) lead to worse outcomes compared with longer (10 to 14 days) courses is low. Most evidence was graded as having moderate quality as the result of imprecision; further research may have an important impact on our confidence in the estimates of effect or may change these estimates.

Implications for research

The studies in this review did not include people with mild or moderate COPD, and further studies are required to compare short‐duration systemic corticosteroid versus conventional, longer‐duration treatment for people with acute exacerbations in this group. Studies should use validated patient‐reported exacerbation outcomes (Jones 2014; Leidy 2014), and this review reinforces the need for researchers to publish results of all completed clinical trials. However, difficulties are associated with recruiting participants to studies with this clinical question in many countries in which early treatment in the community is promoted.

Summary of findings

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Summary of findings for the main comparison. SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD

SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD

Patient or population: patients with acute exacerbations of COPD
Settings: hospital‐initiated treatment
Intervention: SCS treatment for 7 or fewer days
Comparison: SCS treatment for longer than 7 days

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

SCS treatment for longer than 7 days

SCS treatment for 7 or fewer days

Treatment failure
Need for additional treatment
Follow‐up: 10 to 14 days

83 per 1000

61 per 1000
(32 to 117)

OR 0.72
(0.36 to 1.46)

457
(4 studies)

⊕⊕⊕⊝
Moderatea

Equivalent to 22 fewer (95% CI 51 fewer to 34 more)

Relapse
New acute exacerbation or COPD‐related admission
Follow‐up: 14 to 180 days

295 per 1000

304 per 1000
(227 to 395)

OR 1.04
(0.7 to 1.56)

478
(4 studies)

⊕⊕⊕⊝
Moderatea

In one study (Leuppi 2013), hazard ratio for time to re‐exacerbation was 0.95 (95% CI 0.66 to 1.37)

Adverse drug effecthyperglycaemia
Follow‐up: 3 to 14 days

442 per 1000

439 per 1000
(336 to 548)

OR 0.99
(0.64 to 1.53)

345
(2 studies)

⊕⊕⊕⊝
Moderatea

Adverse drug effects
Gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures, depression
Follow‐up: 10 to 180 days

84 per 1000

75 per 1000
(40 to 135)

OR 0.88
(0.46 to 1.7)

503
(5 studies)

⊕⊕⊝⊝
Lowa,b

Mortality
Follow‐up: 14 to 180 days

77 per 1000

71 per 1000
(32 to 147)

OR 0.91
(0.4 to 2.06)

336
(2 studies)

⊕⊕⊕⊝
Moderatea

Length of hospitalisation
(days)
Follow‐up: 3 to 14 days

Mean length of hospitalisation in control groups was
10 days

Mean length of hospitalisation in intervention groups was
0.61 lower (1.51 lower to 0.28 higher)

421
(3 studies)

⊕⊕⊕⊝
Moderatea

Lung function (end of treatment)
FEV1 (L)
Follow‐up: 10 to 14 days

Mean FEV1 in control groups ranged from 0.84 to 1.14 L

Mean lung function (end of treatment) in intervention groups was
0.04 lower (0.19 lower to 0.10 higher)

187
(4 studies)

⊕⊝⊝⊝
Very lowa,c,d,e

Health‐related quality of life (QOL)

Overall score (includes activity limitations, symptoms, fatigue, emotional functioning); scale 0 best to 6 worst; minimum important difference 0.5

Follow‐up: 30 days

Mean QOL score in control groups was 1.24

Mean QOL score in intervention groups was 0.06 higher (‐0.16 lower to 0.28 higher)

271 (1 study)

⊕⊕⊕⊝
Moderatea

*The basis for the assumed risk (e.g. median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; OR: Odds ratio.

GRADE Working Group grades of evidence.
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

aWide confidence intervals include significant benefit or harm (‐1 for imprecision).
bParticipants and physicians not blinded to treatment in one study (‐1 for risk of bias).
cParticipants and physicians not blinded to treatment in one study; however risk of bias for the outcome measurement is considered low.
dHigh risk of attrition bias in one study (‐1 for risk of bias).
eSignificant unexplained heterogeneity (‐1 for inconsistency).

Background

Description of the condition

Chronic obstructive pulmonary disease (COPD) is characterised by persistent airflow limitation that is usually progressive and is associated with an enhanced chronic inflammatory response to noxious particles or gases in the airways and the lung (GOLD 2014). A diagnosis of COPD is considered on a clinical basis in the presence of symptoms such as dyspnoea, chronic cough or sputum production and exposure to known risk factors. Confirmation of COPD diagnosis is based on demonstration of persistent airflow limitation with spirometry, according to the criterion of postbronchodilator forced expiratory volume in one second (FEV1)/forced vital capacity (FVC) ratio less than 0.7, as specified in guidelines included in GOLD (Global Strategy for Diagnosis, Management, and Prevention of COPD) (GOLD 2014). However, heterogeneity (Agusti 2010) and phenotypical variation in COPD (Weatherall 2009) are increasingly recognised. COPD and asthma overlap syndrome are known to have a higher prevalence in older individuals and are associated with more frequent exacerbations (Hardin 2014).

COPD is an important and increasing cause of mortality; it was estimated to be the fifth leading cause of death in the year 2000 and was responsible for 2.75 million deaths (Lopez 2006). Worldwide mortality due to COPD is projected to rise to 4.5 million deaths in 2020, becoming the third leading cause (Murray 1997). Worldwide COPD resulted in 16.5 million years of life lost in 2000, almost 10 million years lived with disability and 26.5 million disability‐adjusted life‐years (Lopez 2006).

The Burden of Lung Disease (BOLD) study (Buist 2007) reported a worldwide prevalence of stage II or greater severity (FEV1 < 80% predicted) of 10.1% (standard error (SE) 4.8) overall, 11.8% (SE 7.9) for men and 8.5% (SE 5.8) for women. International variation in the prevalence and severity of COPD is partially explained by variation in smoking prevalence and other risk factors (Buist 2007).

Exacerbations and co‐morbidities contribute to the varying natural history of COPD in individual patients (GOLD 2014). Exacerbations contribute to long‐term decline in lung function (Donaldson 2002) and reduced physical activity (Donaldson 2005) and are associated with increased risk of death (Soler‐Cataluna 2005). They also have a profound and long‐lasting effect on quality of life (Groenewegen 2001; Wilkinson 2004); in 10% of exacerbations, pre‐exacerbation quality of life was not recovered after three months (Seemungal 2000).

Exacerbations of COPD are a frequent cause of hospitalisation (Donaldson 2006), although exacerbations with less severe symptoms and signs are often managed on an outpatient basis (NICE 2010). Hospital‐at‐home or early discharge services, if available, may be used as an alternative way of caring for patients with exacerbations of COPD who otherwise would need to be admitted or to remain in hospital (NICE 2010). Treatment of patients with exacerbations is a large contributor to the economic burden of COPD (Schermer 2002; Sullivan 2000), and a high proportion of costs is due to hospitalisation (Oostenbrink 2004).

Studies on the frequency of exacerbations usually use an “event‐based” definition based on healthcare utilization (Effing 2009), and different events may be a proxy for severity, with unscheduled clinic or emergency room visits rated “moderate,” and those requiring hospitalisation labelled “severe” (Rodriguez‐Roisin 2000). However, the clinical onset of an acute exacerbation is defined according to symptoms, although no universally agreed upon definition is known (Rodriguez‐Roisin 2000). Type 1 exacerbations were originally defined by Anthonisen on the basis of three major symptoms: increased dyspnoea, sputum volume and sputum purulence; type 2 exacerbations were associated with only two of the major symptoms, and type 3 exacerbations involved one major symptom plus cough, wheeze or symptoms of an upper respiratory tract infection (Anthonisen 1987). A later definition required an increase in two of the "major symptoms" of dyspnoea—sputum volume or sputum purulence—or in one major symptom and one "minor symptom" (wheeze, sore throat, cough or common cold symptoms) for two days (Seemungal 2000). More recently, a standardised measure for assessing frequency, severity and duration of exacerbations of COPD using patient‐reported outcomes has been developed for use in clinical studies: the EXACT (exacerbations of chronic pulmonary disease tool) diary, which consists of 14 items (Leidy 2010; Leidy 2011).

The inflammatory mechanisms underlying the onset and development of COPD exacerbations are complex (Bathoorn 2008), and exacerbations can be precipitated by several factors, and the most common causes are infective (Papi 2006); bacterial pathogens are identified in just over 50% of cases, and viral causes in around 25% (Sethi 2002; Sherk 2000). Non‐infective causes such as air pollution and other environmental conditions that increase airway inflammation may account for 15% to 20% of exacerbations (Sethi 2008). Exacerbations become more frequent and more severe as the severity of COPD increases (Suissa 2012), although the rate at which they occur may reflect an independent susceptibility phenotype—the “frequent exacerbator” (Hurst 2010).

Description of the intervention

The acute inflammatory response to airway infection is influenced by both pathogenic and host factors, resulting in increased airway and systemic inflammation (Sethi 2008). Airway inflammation is significantly increased during exacerbations of COPD, and evidence of increased numbers of neutrophils, lymphocytes and eosinophils is seen in airways and in sputum (Falk 2008; Papi 2006). Systemic inflammation is also present in COPD; many circulating inflammatory mediators are elevated, both in stable COPD and during exacerbations. C‐reactive protein (CRP) is a known marker of systemic inflammation whose levels are elevated during exacerbations; it is a likely participant in the inflammatory cascade (Falk 2008). Theoretical mechanisms for clinical improvement in lung function among patients treated with corticosteroids during exacerbations may include reduction in airway inflammation or a decrease in airway oedema (Wedzicha 2000).

Why it is important to do this review

Systemic corticosteroid use in COPD is associated with potential adverse drug effects, including fluid retention, hypertension, diabetes mellitus, adrenal suppression and osteoporosis (McEvoy 1996). Fracture risk is increased (De Vries 2007; Vestergaard 2007); this is potentially important, as the rate of existing vertebral compression fractures in the COPD population experiencing acute exacerbations, especially among older people with longer duration of disease, is high (Majumdar 2010). Short‐term use of systemic corticosteroids in the treatment of patients with exacerbations of COPD also has adverse effects on respiratory and peripheral muscle strength (Decramer 1994). The risk of adverse drug effects of systemic corticosteroids in COPD rises with increasing frequency of high‐dose systemic corticosteroid use and with increasing cumulative exposure (more than 1 g) (De Vries 2007).

Systemic corticosteroid treatment of patients with acute exacerbations of COPD decreases treatment failure and is associated with early improvement in lung function, breathlessness and arterial hypoxaemia and reduced length of hospital stay (Walters 2014), although in this Cochrane review, the duration of systemic corticosteroid treatment varied, usually described as between three days and 15 days. Guidelines for the management of COPD specify a duration of treatment ranging from seven days to 10 days (GOLD 2014), from seven days to 14 days (NICE 2010) and from 10 days to 14 days (McKenzie 2003). Thus, it is important to define the optimum duration of corticosteroid treatment and to take into account limiting potential adverse effects.

Objectives

To compare the efficacy of short‐duration (seven or fewer days) and conventional longer‐duration (longer than seven days) systemic corticosteroid treatment of adults with acute exacerbations of COPD.

Methods

Criteria for considering studies for this review

Types of studies

Randomised controlled trials (RCTs) comparing short‐duration systemic corticosteroid treatment (seven or fewer days) versus conventional, longer‐duration treatment (longer than seven days).

Types of participants

Adults with an acute exacerbation of COPD. The definition of an acute exacerbation could include any combination of an increase in breathlessness, sputum volume, sputum purulence, cough or wheeze. We excluded studies that included patients with asthma and other lung diseases (e.g. interstitial lung disease, bronchiectasis), unless separate data on participants with COPD alone were available.

Types of interventions

Systemic corticosteroid (SCS) given for a period of seven or fewer days (SCS ≤ 7) versus systemic corticosteroid given for longer than seven days (SCS > 7). Co‐interventions were required to be standardised across groups. We excluded studies in which participants received assisted ventilation (invasive or non‐invasive).

Types of outcome measures

Primary outcomes

  1. Treatment failure (e.g. the need for additional treatment, hospital admission/re‐admission for index episode, return to emergency department, unscheduled physician visit for the index episode).

  2. Relapse after treatment (e.g. treatment for new acute exacerbation, re‐admission or hospitalisation for COPD).

  3. Adverse drug effects.

Secondary outcomes

  1. Mortality.

  2. Lung function.

  3. Length of hospital stay.

  4. Arterial blood gases.

  5. Symptom scores.

  6. Quality of life.

Time period for assessment of continuous outcomes: Early response was measured on or before day seven of treatment, and end of treatment response measurements were made at the time point equivalent to the end of the longer treatment period.

Search methods for identification of studies

Electronic searches

We identified trials from the Cochrane Airways Trials Register, which is maintained by the Information Specialist for the Group. The Cochrane Airways Trials Register contains studies identified from several sources:

  1. Monthly searches of the Cochrane Central Register of Controlled Trials (CENTRAL), through the Cochrane Register of Studies Online (crso.cochrane.org);

  2. Weekly searches of MEDLINE Ovid SP 1946 to date;

  3. Weekly searches of Embase Ovid SP 1974 to date;

  4. Monthly searches of PsycINFO Ovid SP 1967 to date;

  5. Monthly searches of CINAHL EBSCO (Cumulative Index to Nursing and Allied Health Literature) 1937 to date;

  6. Monthly searches of AMED EBSCO (Allied and Complementary Medicine);

  7. Handsearches of the proceedings of major respiratory conferences.

Studies contained in the Trials Register are identified through search strategies based on the scope of Cochrane Airways. Details of these strategies, as well as a list of handsearched conference proceedings are in Appendix 1.

We conducted additional supplementary searches of MEDLINE (PubMed platform, dates covered 1950 to March 2017) and CENTRAL (2017, Issue 3). EMBASE (Embase.com platform, dates covered 1947 to July 2014) searches were conducted in previous versions of this review.. Search strategies used in the Cochrane Airways Register of Trials and other databases are shown in Appendix 2.

For this review update, searches were conducted in the Cochrane Airways Group Register of Trials, and in the other databases in March 2017.

Searching other resources

Bibliographies of RCTs and review articles identified for inclusion were searched for additional papers. Registers of ongoing trials at Clinicaltrials.gov and the WHO trial portal were searched in March 2017.

Data collection and analysis

Selection of studies

All potentially relevant trials were assessed for relevance by at least two review authors (DT, CW), who screened the full text to independently select trials for inclusion and to identify and record reasons for exclusion of ineligible studies. We resolved disagreements through discussion or, if required, we consulted a third person (JW). We identified and excluded duplicates and collated multiple reports of the same study, so that each study (rather than each report) was the unit of interest in the review. We recorded the selection process as a PRISMA flow diagram and in the Characteristics of excluded studies table.

We initially screened all studies using the following criteria.

  1. Acute exacerbation of COPD?

  2. Systemic corticosteroids as intervention?

  3. Comparison of short‐duration (seven or fewer days) versus longer‐duration (longer than seven days) corticosteroid therapy?

  4. Randomised controlled trial?

We noted other arms and reasons for study exclusion when appropriate. We determined exclusion using the criteria listed above and categorised the following as applicable.

  1. Not different durations of steroids.

  2. Not exacerbations of COPD.

  3. Not treatment with systemic corticosteroids.

  4. Review or other type of article.

We also assessed each study for accuracy of the diagnosis of COPD using the following criteria (GOLD 2014).

  1. Did the patient have dyspnoea, chronic cough or sputum production?

  2. Was there a history of exposure to risk factors including tobacco smoke; occupational dusts and chemicals; and smoke from home cooking and heating fuel?

  3. Was a spirometry measurement of the FEV1/FVC ratio less than 0.7 post bronchodilator?

Data extraction and management

We used a data collection form to document study characteristics and outcome data. Two review authors (DT, CW) extracted the following study characteristics from included studies.

  1. Methods: study design, total duration of study, number of study centres and locations, study setting, withdrawals and date of study.

  2. Participants: N, mean age, age range, gender, COPD diagnostic criteria, diagnostic criteria for exacerbation, baseline lung function, smoking history, inclusion criteria and exclusion criteria.

  3. Interventions: systemic corticosteroid treatment dose/schedule, concomitant medications and excluded medications.

  4. Outcomes: primary and secondary outcomes specified and collected and time points reported.

  5. Notes: funding for trial and notable conflicts of interest of trial authors.

Two review authors (two of JW, DT, CW) independently extracted outcome data from included studies. Results presented in graphical form were extracted using the software Plot Digitizer. When results were available as means with interquartile ranges, standard deviation was based on the width of the interquartile range—approximately 1.35. standard deviations.

Data were entered into Review Manager (by JW, DT, CW) and were double‐checked by a second review author. We checked that data were entered correctly by comparing data presented in the systematic review against data provided in the study reports.

Assessment of risk of bias in included studies

Two review authors (of JW, CW, DT) independently assessed the risk of bias for each study using the criteria outlined in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011). We resolved disagreements by discussion or by involving another review author. We assessed risk of bias according to the following domains.

  1. Random sequence generation.

  2. Allocation concealment.

  3. Blinding of participants and personnel.

  4. Blinding of outcome assessment.

  5. Incomplete outcome data.

  6. Selective outcome reporting.

  7. Presence of other bias(es).

We graded each potential source of bias as high, low or unclear, and provided a quote from the study report, together with a justification for our judgement, in the 'Risk of bias' table. We summarised risk of bias judgements across different studies for each of the domains listed. When information on risk of bias was related to unpublished data or correspondence with a trialist, we noted this in the 'Risk of bias' table.

When considering treatment effects, we took into account the risk of bias for studies that contributed to this outcome.

Measures of treatment effect

For continuous variables, data were analysed as mean differences (MDs) with 95% confidence intervals (CIs). Standardised mean differences (SMDs) with 95% CIs were used when different scales of measurement had been used for an outcome. The SMD is a statistic that expresses the difference in means between treatment groups in units of the pooled standard deviation. Dichotomous outcomes were analysed using Mantel‐Haenszel odds ratios with 95% CIs. When events were rare, we employed the Peto odds ratio. Scale data were entered with a consistent direction of effect.

We undertook meta‐analyses only when these were meaningful—when treatments, participants and the underlying clinical question were similar. When data were skewed, we described them narratively.

For 'time‐to‐event' outcomes such as log hazard ratios, the fixed‐effect generic inverse variance outcome was used to combine results. This method provides a weighted average of the effect estimates of separate studies (Higgins 2011). Number needed to treat for an additional beneficial outcome was calculated from the pooled odds ratio and its confidence interval, using baseline risk in the control group.

Unit of analysis issues

We analysed dichotomous data using participants as the unit of analysis. For continuous data, the MD based on change from baseline was preferred over the MD based on absolute values when both were available.

Dealing with missing data

We contacted investigators to obtain missing numerical outcome data when possible (e.g. when a study was reported as an abstract only). When this was not possible, and when missing data were thought to introduce serious bias, we performed a sensitivity analysis to explore the impact of including such studies in the overall assessment of results.

Assessment of heterogeneity

An assessment of possible heterogeneity, when the null hypothesis is that all studies are evaluating the same effect, was carried out for pooled effects using a Breslow‐Day test of heterogeneity; the Chi2 test measures the deviation of observed effect sizes from an underlying overall effect. This test has low power for detecting true heterogeneity when studies have small sample size or are few in number, hence we used a P value of 0.10 (Deeks 2008). In addition, the I2 statistic, which describes the percentage of total variation across studies that is due to heterogeneity rather than to chance (Higgins 2003), was used. Statistical heterogeneity was interpreted as follows: 0% to 40% might not be important, 30% to 60% may represent moderate heterogeneity and 50% to 90% may represent substantial heterogeneity (Higgins 2011).

We assessed clinical and methodological heterogeneity by recording differences in study design and participant characteristics between individual studies. When we found substantial heterogeneity, we reported this and explored possible causes by performing prespecified subgroup analysis.

Assessment of reporting biases

We tried to minimise reporting bias from non‐publication of studies or selective outcome reporting by using a broad search strategy. We checked references of included studies and relevant systematic reviews, and we contacted study authors to request additional outcome data. To assess the presence of publication bias, we visually inspected funnel plots when 10 or more studies contributed to the analysis for a specified outcome.

Data synthesis

Data were pooled using Review Manager 5.3 (RevMan 2014). We used a fixed‐effect model, and when heterogeneity could not be explained, we performed a sensitivity analysis using a random‐effects model. We presented the findings of our primary outcomes in a 'Summary of findings' table according to recommendations provided in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011) (generated with the use of GradePro software).

Subgroup analysis and investigation of heterogeneity

When we detected statistically significant heterogeneity (P value < 0.10), several options were available. We explored the clinical diversity of studies through prespecified subgroup analyses by comparing the following factors.

  1. Definition of COPD.

  2. Aspects of study quality (e.g. concealment of allocation).

  3. Characteristics of participants.

We considered random‐effects analysis methods (DerSimonian 1986) when heterogeneity was unexplained and study sizes were large, or when study findings were not pooled.

We performed subgroup analyses, stratified by the following variables, when possible.

  1. Inpatient versus outpatient.

  2. Studies that included participants previously treated with corticosteroids (inhaled and systemic).

Sensitivity analysis

In assessment of heterogeneity, possible causes arising from details of study design were considered. Sensitivity analyses were performed using a random‐effects model versus a fixed‐effect model for risk of bias and other potential confounders.

Results

Description of studies

Results of the search

Of 644 unique records obtained in the 2011 searches (Figure 1), seven studies met the inclusion criteria, of which four reported data and contributed to the original meta‐analysis (Walters 2011). One ongoing study (Reid 2010) suspended recruitment in 2010, but no data are available. Searches from 2011 to 2014 yielded 284 results in the Cochrane Airways Group Register of Trials, 39 results in CINAHL, 168 in EMBASE and 102 in CENTRAL. When the inclusion criteria were applied, one new study was identified for inclusion (Leuppi 2013), which was listed as an ongoing trial in 2011.


1 Study flow diagram.

1 Study flow diagram.

In March 2017, we ran an update search. This returned 417 references of which 13 were duplicate, 390 were judged as irrelevant based on title and abstract alone. 14 full text articles were assessed, 13 excluded (7 Wrong intervention, 4 Wrong comparator, 2 Wrong study design), 1 citation belonged to an already included study (Leuppi 2013).

One on‐going study was identified as of March 2017 (Leuppi 2017).

Included studies

We have provided details of the eight included studies in the Characteristics of included studies table and a comparison of their main inclusion criteria and characteristics in Table 1.

Open in table viewer
Table 1. Study characteristics

Study ID/Setting

Inclusion criteria

AE definition

N participants included/Completing

Mean age, years

% males/ % smokers

Prestudy SCS use, %

SCS ≤ 7 days

SCS > 7 days

Definition of treatment failure

Chen 2005 China/ inpatients

2 years of continuous productive cough, FEV1/FVC post BD < 0.7, FEV1 < 80% predicted. No respiratory failure, diabetes or bronchial asthma

At least 2 of 3 symptoms: increased sputum or dyspnoea or purulent sputum

86/81

71

75/44

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg/d 10 days + 15 mg/d 5 days

Not known

Gomaa 2008 (abstract only)

FEV1 < 50% predicted, no respiratory acidosis

Not stated

42/Not known

Not stated

Not stated

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg 15 days

Outcome not reported

Leuppi 2013 Switzerland/5 sites

Age > 40 years, smoking history ≥ 20 pack‐years

At least 2 of the following: change in baseline dyspnoea, cough or sputum quantity/purulence

314/296

69

60/45

20

5 days: days 1 to 4 methylprednisolone 40 mg, days 2 to 5 oral prednisolone 40 mg

14 days: days 1 to 4 methylprednisolone 40 mg, days 2 to 14 oral 40 mg prednisolone

Received open‐label glucocorticoids during index exacerbation

Rahman 2004 (abstract only) Bangladesh/1 site

Not stated

Not stated

Not stated

Not stated

Not stated

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg 14 days

Outcome not reported

Salam 1998 (abstract only) USA/Unknown sites

Not stated

Not stated

21/Not known

Not stated

Not stated

None in previous month

IV CS 3 days

IV CS 3 days + 7 days OCS

Outcome not reported

Sayiner 2001 Turkey/1 site

FEV1 < 35% predicted, PYH > 20, no respiratory failure requiring ventilation

Not stated, requiring admission

36/34

65

94/Not stated

None in previous month

IV methylprednisone 0.5 mg/kg qds 3 days

IV methylprednisone 0.5 mg/kg qds 3 days, bd 3 days, od 4 days

Required open‐label steroid treatment

Sirichana 2008 (abstract and author data) Thailand/1 site

Age > 40 years, symptoms > 24 hours

Increase in at least 2 of 3 symptoms—dyspnoea, sputum volume, sputum purulence; requiring admission

48/42

73

88/Not stated

None in previous month

Prednisolone 30 mg 5 days

Prednisolone 30 mg 10 days

Outcome not reported

Wood‐Baker 1997 (abstract and author data) Australia & New Zealand/2 sites

Age > 40 years; > 10 pack‐year smoking history; FEV1 < 50% predicted

Not stated, requiring admission

38/28

71

63/Not stated

None for current AEs, no long‐term OS > 5 mg/d

Prednisolone 2.5 mg/kg orally daily for 3 days

Prednisolone 0.6 mg/kg orally daily for 7 days followed by prednisolone 0.3 mg/kg orally daily for 7 days

Lack of progress according to attending physician during treatment

All eight studies with a total of 582 participants were parallel‐group RCTs comparing systemic corticosteroid treatment for seven or fewer days versus treatment for longer than seven days in people with an acute exacerbation of COPD; all were conducted in hospital settings. These studies were published between 1997 and 2013. Two studies reported the definition for COPD diagnosis (Chen 2005; Leuppi 2013), and two studies specified the inclusion of participants with an FEV1 below 50% predicted (Gomaa 2008; Wood‐Baker 1997) or below 35% predicted (Sayiner 2001). Two studies (Leuppi 2013; Sirichana 2008) provided a specific symptom‐based definition of an acute exacerbation.

Studies varied in size from 21 to 314 participants; the mean age of participants was between 65 and 73 years, and the proportion of female participants ranged from 6% to 42% (in four studies that reported these data). Participants had severe to very severe COPD; in two studies baseline mean FEV1 ranged from 0.5 to 0.8 litres, and in two other studies baseline mean FEV1 ranged from 25% to 33% predicted.

Five studies used only oral prednisolone (Chen 2005; Gomaa 2008; Rahman 2004; Sirichana 2008; Wood‐Baker 1997) at a dose of 30 mg daily, except Wood‐Baker 1997, which provided oral prednisolone 2.5 mg/kg in the short‐duration arm and a tapered dose (0.6 mg/kg/d for seven days followed by 0.3 mg/kg/d for seven days) in the longer‐duration arm. Three studies used intravenous corticosteroid initially in both arms for 24 or 72 hours: methylprednisolone in Leuppi 2013 and Sayiner 2001, and an unspecified intravenous corticosteroid in Salam 1998. Participants then received systemic corticosteroids intravenously for seven days in Sayiner 2001 and orally for seven days in Salam 1998 in the longer‐duration arm. All participants in Leuppi 2013 received oral prednisone from day 2 onwards for the appropriate treatment duration.

Duration of treatment in the short‐course arm was three days in Salam 1998, Sayiner 2001 and Wood‐Baker 1997; five days in Leuppi 2013 and Sirichana 2008; and seven days in Chen 2005, Gomaa 2008 and Rahman 2004. The duration of longer‐course treatment was 10 days in Salam 1998, Sayiner 2001 and Sirichana 2008; 14 days in Gomaa 2008, Leuppi 2013, Rahman 2004 and Wood‐Baker 1997; and 15 days in Chen 2005.

Three studies were published as full papers (Chen 2005; Leuppi 2013; Sayiner 2001), and additional data were supplied by the study author for Chen 2005. Of five studies published only as abstracts in conference proceedings, data were supplied by authors for Sirichana 2008 and Wood‐Baker 1997. Despite at least two requests, no data were made available for Gomaa 2008, Rahman 2004 and Salam 1998.

Excluded studies

A total of 23 studies with reasons for exclusion are listed in Characteristics of excluded studies.

Risk of bias in included studies

The methodological quality of the published included trials was good; they were determined to have low risk of selection, performance, detection and attrition bias. Risk of bias was unclear in studies available only as abstracts (Figure 2 and Figure 3).


Risk of bias summary: review authors' judgements about each item for each included study.

Risk of bias summary: review authors' judgements about each item for each included study.


Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Allocation

In four studies (Chen 2005; Leuppi 2013; Sayiner 2001; Wood‐Baker 1997) the randomisation procedure was adequate, but sequence generation was unclear. Allocation concealment was adequate in four studies (Chen 2005; Leuppi 2013; Sayiner 2001; Sirichana 2008) but was not described in four studies.

Blinding

Four studies were double blind (Chen 2005; Leuppi 2013; Sayiner 2001; Wood‐Baker 1997). One study (Sirichana 2008) was not blinded to participants or investigators. Blinding was unclear in the three other studies, although one study (Gomaa 2008) stated that the study was single blinded but provided no further details.

Incomplete outcome data

Incomplete data were adequately addressed in four studies (Chen 2005; Leuppi 2013; Sayiner 2001; Wood‐Baker 1997), but risk of bias was judged high in Sirichana 2008 and was unclear in three studies.

Selective reporting

Three studies were assessed as free of selective reporting (Leuppi 2013; Sayiner 2001; Wood‐Baker 1997), but risk of bias was unclear in five studies.

Effects of interventions

See: Summary of findings for the main comparison SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD

Primary outcomes

1.1 Treatment failure

Four studies reported treatment failure that occurred during the index exacerbation, and the definition was provided in three studies (Table 1). No significant difference was noted in the likelihood of treatment failure between systemic corticosteroid for seven or fewer days and longer than seven days (n = 457; odds ratio (OR) 0.72, 95% confidence interval (CI) 0.36 to 1.46; Analysis 1.1; Figure 4), and no statistical heterogeneity was observed. This result is equivalent to 22 fewer treatment failures per 1000 (95% CI 51 fewer to 34 more). The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.


Forest plot outcome: treatment failure comparing systemic corticosteroids for ≤ 7 days vs > 7 days.

Forest plot outcome: treatment failure comparing systemic corticosteroids for ≤ 7 days vs > 7 days.

1.2 Relapse

Relapse was measured as a new acute exacerbation or hospital admission for COPD in four studies: Chen 2005 (follow‐up period not stated), Sayiner 2001 and Leuppi 2013 (six‐month follow‐up) and Sirichana 2008 (30‐day follow‐up). No significant difference was reported between systemic corticosteroid use for seven or fewer days and for longer than seven days (n = 478; OR 1.04, 95% CI 0.7 to 1.56; Analysis 1.2; Figure 5), and no statistical heterogeneity was observed. The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.


Forest plot of comparison: 1 Systemic corticosteroids for 7 or fewer days vs longer than seven days, outcome: 1.2 Relapse.

Forest plot of comparison: 1 Systemic corticosteroids for 7 or fewer days vs longer than seven days, outcome: 1.2 Relapse.

1.3 Time to re‐exacerbation

Time to next COPD exacerbation, defined as "acute‐onset worsening of the patient’s condition beyond day‐to‐day variations requiring interaction with a healthcare provider which could occur during the index exacerbation or during follow‐up," over six months of follow‐up was reported in one study (Leuppi 2013). This study adopted an a priori non‐inferiority definition, by which the proportion of participants with re‐exacerbation during follow‐up should be no more than 65% compared with 50% for standard treatment for an exacerbation, yielding a critical hazard ratio of 1.515. Time to the next exacerbation did not differ in this one large study, which was powered to detect non‐inferiority and compared five days versus 14 days of systemic corticosteroid treatment (n = 311; hazard ratio (HR) 0.95, 95% CI 0.66 to 1.37; Analysis 1.3).

1.4 to 1.6 Adverse effects

1.4 Hyperglycaemia: In two studies (Leuppi 2013; Sayiner 2001) no difference was noted in the likelihood of hyperglycaemia between systemic corticosteroid for seven or fewer days and longer than seven days (n = 345; OR 0.99, 95% CI 0.64 to 1.53; Analysis 1.4), and no heterogeneity was observed. The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.

1.5 Hypertension: In one trial (Leuppi 2013)no difference was noted in the likelihood of hypertension between systemic corticosteroid for seven or fewer days and longer than seven days (n = 311; OR 0.61, 95% CI 0.31 to 1.22; Analysis 1.5).

1.6 Other adverse effects were reported in five studies and included gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures and depression. No difference was noted in the likelihood of another adverse event between systemic corticosteroids for seven or fewer days and longer than seven days (n = 503; OR 0.89, 95% CI 0.46 to 1.69; Analysis 1.6). The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.

Secondary outcomes

1.7 Mortality

In two studies the likelihood of mortality did not differ between systemic corticosteroid for seven or fewer days and longer than seven days (n = 336; OR 0.91, 95% CI 0.40 to 2.06; Analysis 1.7). The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.

1.8 Length of hospitalisation

In three studies no difference was noted in length of hospital stay between systemic corticosteroid for seven or fewer days and longer than seven days (n = 421; mean difference (MD) ‐0.61 days, 95% CI ‐1.51 to 0.28; Analysis 1.8). The outcome was downgraded for imprecision and was rated as having moderate quality because the confidence intervals for the pooled effect included important benefit and potential harm.

1.9 to 1.14 Lung function

In three studies no difference was noted in absolute FEV1 measured within seven days between systemic corticosteroid for seven or fewer days and longer than seven days (n = 96; MD ‐0.07 litres, 95% CI ‐0.19 to 0.05; Analysis 1.9), and no heterogeneity was observed. Leuppi 2013 reported lung function as FEV1 percentage predicted and noted no difference between systemic corticosteroid for seven or fewer days and longer than seven days (n = 289; MD 0.76%, 95% CI ‐3.15 to 4.66; Analysis 1.10). In three studies no difference was noted in early response of FVC between systemic corticosteroid for seven or fewer days and longer than seven days (n = 97; MD 0.01 L, 95% CI ‐0.20 to 0.22; Analysis 1.11), and no statistical heterogeneity was observed.

For lung function measured at the end of treatment in four studies, no difference was noted in FEV1 between systemic corticosteroid for seven or fewer days and longer than seven days (n = 187; MD ‐0.04 litres, 95% CI ‐0.19 to 0.10; Analysis 1.12); important heterogeneity was observed (Chi² = 7.17, df = 3 (P value 0.07), I² = 58%). The outcome was rated as having very low quality and was downgraded for imprecision because the confidence intervals for the pooled effect included important benefit and potential harm, and risk of attrition bias and inconsistency were due to unexplained heterogeneity. In Leuppi 2013, no difference was noted in FEV1 percentage predicted at 30 days between systemic corticosteroid for seven or fewer days and more than seven days (n = 289; MD 1.29%, 95% CI ‐3.35 to 5.93; Analysis 1.13). In three studies no difference was noted in FVC at the end of treatment between systemic corticosteroid for seven or fewer days and longer than seven days (n = 99; MD ‐0.12, 95% CI ‐0.33 to 0.09; Analysis 1.14), and no heterogeneity was observed.

1.15 to 1.17 Arterial blood gases

Sayiner 2001 reported partial pressure of oxygen in arterial blood (PaO2) before seven days (n = 34). No difference was noted between treatment with systemic corticosteroid for seven or fewer days and longer than seven days (MD ‐0.20 mmHg; 95% CI ‐9.21 to 8.81; Analysis 1.15).

In two studies (n = 121) at completion of treatment, no difference was noted in PaO2 after 10 to 14 days of follow‐up between systemic corticosteroid for seven or fewer days and longer than seven days (MD ‐1.38 mmHg; 95% CI ‐4.96 to 2.21; Analysis 1.16).

In Sayiner 2001 (n = 34) no difference was noted in partial pressure of carbon dioxide in arterial blood (PaCO2) after three days (MD ‐1.80 mmHg, 95% CI ‐11.14 to 7.54) or after 10 days (MD 1.50 mmHg, 95% CI ‐5.20 to 8.20) between treatment with systemic corticosteroid for seven or fewer days and longer than seven days (Analysis 1.17).

1.18 to 1.19 Symptom scores

In two studies no differences were noted in dyspnoea scores when measured before seven days between systemic corticosteroid for seven or fewer days and longer than seven days (n = 320; standardised mean difference (SMD) ‐0.08, 95% CI ‐0.29 to 0.14; Analysis 1.18), and no statistical heterogeneity was observed. When expressed on the Medical Research Council (MRC) scale (1 to 5), this would equate to 0.1 units better (95% CI 0.4 better to 0.2 worse).

In four studies at the end of treatment, no difference was noted in dyspnoea scores between systemic corticosteroid for seven or fewer days and longer than seven days (n = 404; SMD 0.16, 95% CI ‐0.03 to 0.36; Analysis 1.19),and moderate heterogeneity was observed (Chi² = 5.89, df = 3 (P value 0.12), I² = 49%). When expressed on the MRC scale (1 to 5), this would equate to 0.2 units worse (95% CI 0.04 better to 0.45 worse).

1.20 to 1.21 Quality of life

Health‐related quality of life was assessed in Leuppi 2013 by using the acute bronchitis health‐related quality‐of‐life interview, which measures changes in health‐related quality of life among patients treated for chronic lung disease; it consists of 22 items in four domains: activity‐related limitations (six items); effects of symptoms (eight items); fatigue (four items); and emotional functioning (four items). Each item is rated on a 7‐point scale, and a difference of 0·5 points is taken to be the smallest important difference (Evans 2002). No difference was reported in overall score between systemic corticosteroid for seven or fewer days and longer than seven days when measured before seven days (n = 290; MD 0.03, 95% CI ‐0.15 to 0.21; Analysis 1.20) or after 30 days (n = 263; MD 0.07, 95% CI ‐0.11 to 0.25; Analysis 1.21).

Discussion

Summary of main results

SCS treatment for seven or fewer days compared with SCS treatment for longer than seven days for acute exacerbations of COPD

Please see summary of findings Table for the main comparison.

The likelihood of treatment failure did not differ between treatment with systemic corticosteroids for seven or fewer days and longer than seven days over 10 to 14 days of follow‐up in four studies, although wide confidence intervals around the estimate were reported (457 participants; odds ratio (OR) 0.72, 95% confidence interval (CI) 0.36 to 1.46). This difference equates to 22 fewer people experiencing treatment failure per 1000 (95% CI 51 fewer to 34 more) for short‐duration corticosteroid treatment. Similarly, no difference was noted for re‐exacerbation over 14 to 180 days of follow‐up in four studies (478 participants; OR 1.04, 95% CI 0.7 to 1.56); this equates to nine fewer people with re‐exacerbation per 1000 (95% CI 68 fewer to 100 more) for longer‐duration corticosteroid treatment. Time to the next COPD exacerbation did not differ in one large study, which was powered to detect non‐inferiority and compared five days versus 14 days of systemic corticosteroid treatment (n = 311; hazard ratio 0.95, 95% CI 0.66 to 1.37).

The likelihood of adverse drug effects when systemic corticosteroids given for seven or fewer days were compared with systemic corticosteroids given for longer than seven days did not differ for hyperglycaemia in two studies with data of moderate quality (n = 345; OR 0.99, 95% CI 0.64 to 1.53), nor for a range of other drug effects in five studies with data of low quality (n = 503; OR 0.88, 95% CI 0.46 to 1.69). Mortality during follow‐up of between 14 days and 180 days did not differ in two studies (n = 336; OR 0.91, 95% CI 0.40 to 2.06) with data of moderate quality.

No differences in length of hospitalisation were noted in three studies (n = 421; MD ‐0.61 days, 95% CI ‐1.51 to 0.28) with data of moderate quality, and no differences in lung function at the end of treatment were reported in four studies (n = 187; mean difference (MD) in forced expiratory volume in one second (FEV1) ‐0.04 L, 95% CI ‐0.19 to 0.10) with data of very low quality. No difference in health‐related quality of life was observed in one study with data of moderate quality.

Overall completeness and applicability of evidence

Five of the eight included studies were not published as full articles. Meta‐analyses were limited by the need to omit three studies for which no data could be extracted from abstracts, or for which no data were supplied by study authors (Gomaa 2008; Rahman 2004; Salam 1998). The small number of trials meant that no subgroup analyses were performed.

One study (Wood‐Baker 1997) closed prematurely because of the difficulty of recruiting participants who met the inclusion criterion stating that participants should not have commenced oral steroid treatment before recruitment. This stipulation also caused low recruitment for the ongoing study (Reid 2010). In many countries this is likely to be a barrier to conducting inpatient studies comparing corticosteroid treatment of shorter duration versus conventional duration of up to 14 days, as guidelines and action plans recommend early initiation of therapy.

As this review excluded studies in which participants received assisted ventilation (invasive or non‐invasive), the findings are not generalisable to people on assisted ventilation. Doses of systemic corticosteroid given to patients admitted to an intensive care unit (ICU) who may require assisted ventilation usually are much higher than those given in the studies included in this review (Kiser 2014). An observational study evaluating corticosteroid use in patients admitted to the ICU with an exacerbation of chronic obstructive pulmonary disease (COPD) concluded that fewer deaths and shorter stays in hospital occurred among people treated with systemic corticosteroid at doses equivalent to less than 240 mg per day of methylprednisolone. An observational study involving patients admitted to a non‐intensive care setting with an exacerbation of COPD who received systemic corticosteroids did not assess duration of treatment; this study found that low‐dose corticosteroids (20 to 80 mg/d prednisone equivalent) administered orally were not associated with worse outcomes than were seen with high‐dose intravenous therapy (120 to 800 mg/d prednisone equivalent) during the first two hospital days (Lindenauer 2010).

Quality of the evidence

Studies that contributed to the meta‐analysis were at low risk of selection bias, although one study was at high risk of performance and detection bias from lack of blinding. Some heterogeneity between studies was observed with regard to the inclusion criteria. Many studies did not provide details of their inclusion criteria, including their definition of an acute exacerbation of COPD. Only three studies specified the severity of COPD in participants based on their lung function reading (FEV1) upon admission. Thresholds to define severity included FEV1 less than 50% predicted in Gomaa 2008 and Wood‐Baker 1997, and less than 35% predicted in Sayiner 2001. Variation in the systemic corticosteroid used in the included studies was reported: Five used oral prednisolone, one at high then tapering dose (Wood‐Baker 1997), and two used intravenous corticosteroid. However, oral and intravenous corticosteroids have been shown to have equal efficacy and should not, therefore, contribute to any heterogeneity (Therapeutic Guidelines 2009). Sensitivity analyses according to risks of bias due to lack of blinding or route of corticosteroid administration had no significant effects on pooled results (Table 2). Duration of follow‐up varied between studies and was not stated in four studies. Follow‐up periods may have been too short to allow detection of potential differences in relapse, mortality and readmission. Lack of data for pooling limited the analysis of some outcomes that are important to patients, such as quality of life.

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Table 2. Sensitivity analyses

Excluding Sirichana (not blinded)

All studies

Relapse

1.01 (0.66 to 1.55)

1.04 (0.70 to 1.56)

FEV1 early

‐0.09 (‐0.22 to 0.05)

‐0.07 (‐0.19 to 0.05)

FEV1 end

‐0.06 (‐0.23 to 0.11)

‐0.04 (‐0.19 to 0.10)

FVC early

‐0.00 (‐0.25 to 0.25)

0.01 (‐0.20 to 0.22)

FVC end

‐0.14 (‐0.38 to 0.09)

‐0.12 (‐0.33 to 0.09)

Adverse event—other

0.94 (0.48 to 1.82)

0.89 (0.46 to 1.69)

Excluding Sayiner (IV SCS)

All studies

Treatment failure

0.66 (0.32 to 1.37)

0.72 (0.36 to 1.46)

Relapse

1.02 (0.67 to 1.56)

1.04 (0.70 to 1.56)

Adverse event—hyperglycaemia

0.99 (0.63 to 1.54)

0.99 (0.64 to 1.53)

Adverse event—other

0.89 (0.46 to 1.69)

0.89 (0.46 to 1.69)

FEV1 early

‐0.02 (‐0.19 to 0.16)

‐0.07 (‐0.19 to 0.05)

FEV1 end

0.03 (‐0.06 to 0.12)

‐0.04 (‐0.19 to 0.10)

FVC early

0.12 (‐0.18 to 0.42)

0.01 (‐0.20 to 0.22)

FVC end

‐0.06 (‐0.34 to 0.22)

‐0.12 (‐0.33 to 0.09)

Potential biases in the review process

The review authors made every effort to identify all relevant published and unpublished studies by using additional methods to identify studies that might not have been found during the main electronic search (e.g. searching drug company databases and clinical trial registration sites, checking reference lists). We did not routinely contact individual trial authors for additional data unless outcomes were clearly selectively reported. All review authors adhered to the most recent best practice guidelines in terms of study selection, resolution of disagreements, data extraction and analysis to reduce bias and error. We included all data obtained from the included studies, even those from studies at higher risk of bias with regard to participant withdrawals, such as Sirichana 2008, but we performed sensitivity analysis to check whether omitting the study changed the results. We obtained data for one study (Wood‐Baker 1997) from an author from this review team; however, data extraction and analysis were performed in the same way as for the other studies.

1 Study flow diagram.
Figures and Tables -
Figure 1

1 Study flow diagram.

Risk of bias summary: review authors' judgements about each item for each included study.
Figures and Tables -
Figure 2

Risk of bias summary: review authors' judgements about each item for each included study.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figures and Tables -
Figure 3

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Forest plot outcome: treatment failure comparing systemic corticosteroids for ≤ 7 days vs > 7 days.
Figures and Tables -
Figure 4

Forest plot outcome: treatment failure comparing systemic corticosteroids for ≤ 7 days vs > 7 days.

Forest plot of comparison: 1 Systemic corticosteroids for 7 or fewer days vs longer than seven days, outcome: 1.2 Relapse.
Figures and Tables -
Figure 5

Forest plot of comparison: 1 Systemic corticosteroids for 7 or fewer days vs longer than seven days, outcome: 1.2 Relapse.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 1 Treatment failure.
Figures and Tables -
Analysis 1.1

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 1 Treatment failure.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 2 Relapse.
Figures and Tables -
Analysis 1.2

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 2 Relapse.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 3 Time to re‐exacerbation.
Figures and Tables -
Analysis 1.3

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 3 Time to re‐exacerbation.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 4 Adverse effect—hyperglycaemia.
Figures and Tables -
Analysis 1.4

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 4 Adverse effect—hyperglycaemia.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 5 Adverse effect—hypertension.
Figures and Tables -
Analysis 1.5

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 5 Adverse effect—hypertension.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 6 Other adverse effects—gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures, depression.
Figures and Tables -
Analysis 1.6

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 6 Other adverse effects—gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures, depression.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 7 Mortality.
Figures and Tables -
Analysis 1.7

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 7 Mortality.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 8 Length of hospitalisation.
Figures and Tables -
Analysis 1.8

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 8 Length of hospitalisation.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 9 FEV1 (L) (early).
Figures and Tables -
Analysis 1.9

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 9 FEV1 (L) (early).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 10 FEV1 % predicted (6 days).
Figures and Tables -
Analysis 1.10

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 10 FEV1 % predicted (6 days).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 11 FVC (L) (early).
Figures and Tables -
Analysis 1.11

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 11 FVC (L) (early).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 12 FEV1 (L) end of treatment.
Figures and Tables -
Analysis 1.12

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 12 FEV1 (L) end of treatment.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 13 FEV1 % predicted 30 days.
Figures and Tables -
Analysis 1.13

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 13 FEV1 % predicted 30 days.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 14 FVC (L) end of treatment.
Figures and Tables -
Analysis 1.14

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 14 FVC (L) end of treatment.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 15 PaO2 (mmHg) (early).
Figures and Tables -
Analysis 1.15

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 15 PaO2 (mmHg) (early).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 16 PaO2 (mmHg) end of treatment.
Figures and Tables -
Analysis 1.16

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 16 PaO2 (mmHg) end of treatment.

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 17 PaCO2 (mmHg).
Figures and Tables -
Analysis 1.17

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 17 PaCO2 (mmHg).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 18 Symptoms—dyspnoea (early).
Figures and Tables -
Analysis 1.18

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 18 Symptoms—dyspnoea (early).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 19 Symptoms—dyspnoea (15 days).
Figures and Tables -
Analysis 1.19

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 19 Symptoms—dyspnoea (15 days).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 20 Quality of life—overall (6 days).
Figures and Tables -
Analysis 1.20

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 20 Quality of life—overall (6 days).

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 21 Quality of life—overall (30 days).
Figures and Tables -
Analysis 1.21

Comparison 1 Systemic corticosteroids for 7 or fewer days vs longer than 7 days, Outcome 21 Quality of life—overall (30 days).

Summary of findings for the main comparison. SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD

SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD

Patient or population: patients with acute exacerbations of COPD
Settings: hospital‐initiated treatment
Intervention: SCS treatment for 7 or fewer days
Comparison: SCS treatment for longer than 7 days

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

SCS treatment for longer than 7 days

SCS treatment for 7 or fewer days

Treatment failure
Need for additional treatment
Follow‐up: 10 to 14 days

83 per 1000

61 per 1000
(32 to 117)

OR 0.72
(0.36 to 1.46)

457
(4 studies)

⊕⊕⊕⊝
Moderatea

Equivalent to 22 fewer (95% CI 51 fewer to 34 more)

Relapse
New acute exacerbation or COPD‐related admission
Follow‐up: 14 to 180 days

295 per 1000

304 per 1000
(227 to 395)

OR 1.04
(0.7 to 1.56)

478
(4 studies)

⊕⊕⊕⊝
Moderatea

In one study (Leuppi 2013), hazard ratio for time to re‐exacerbation was 0.95 (95% CI 0.66 to 1.37)

Adverse drug effecthyperglycaemia
Follow‐up: 3 to 14 days

442 per 1000

439 per 1000
(336 to 548)

OR 0.99
(0.64 to 1.53)

345
(2 studies)

⊕⊕⊕⊝
Moderatea

Adverse drug effects
Gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures, depression
Follow‐up: 10 to 180 days

84 per 1000

75 per 1000
(40 to 135)

OR 0.88
(0.46 to 1.7)

503
(5 studies)

⊕⊕⊝⊝
Lowa,b

Mortality
Follow‐up: 14 to 180 days

77 per 1000

71 per 1000
(32 to 147)

OR 0.91
(0.4 to 2.06)

336
(2 studies)

⊕⊕⊕⊝
Moderatea

Length of hospitalisation
(days)
Follow‐up: 3 to 14 days

Mean length of hospitalisation in control groups was
10 days

Mean length of hospitalisation in intervention groups was
0.61 lower (1.51 lower to 0.28 higher)

421
(3 studies)

⊕⊕⊕⊝
Moderatea

Lung function (end of treatment)
FEV1 (L)
Follow‐up: 10 to 14 days

Mean FEV1 in control groups ranged from 0.84 to 1.14 L

Mean lung function (end of treatment) in intervention groups was
0.04 lower (0.19 lower to 0.10 higher)

187
(4 studies)

⊕⊝⊝⊝
Very lowa,c,d,e

Health‐related quality of life (QOL)

Overall score (includes activity limitations, symptoms, fatigue, emotional functioning); scale 0 best to 6 worst; minimum important difference 0.5

Follow‐up: 30 days

Mean QOL score in control groups was 1.24

Mean QOL score in intervention groups was 0.06 higher (‐0.16 lower to 0.28 higher)

271 (1 study)

⊕⊕⊕⊝
Moderatea

*The basis for the assumed risk (e.g. median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; OR: Odds ratio.

GRADE Working Group grades of evidence.
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

aWide confidence intervals include significant benefit or harm (‐1 for imprecision).
bParticipants and physicians not blinded to treatment in one study (‐1 for risk of bias).
cParticipants and physicians not blinded to treatment in one study; however risk of bias for the outcome measurement is considered low.
dHigh risk of attrition bias in one study (‐1 for risk of bias).
eSignificant unexplained heterogeneity (‐1 for inconsistency).

Figures and Tables -
Summary of findings for the main comparison. SCS treatment for 7 or fewer days compared with SCS treatment for longer than 7 days for acute exacerbations of COPD
Table 1. Study characteristics

Study ID/Setting

Inclusion criteria

AE definition

N participants included/Completing

Mean age, years

% males/ % smokers

Prestudy SCS use, %

SCS ≤ 7 days

SCS > 7 days

Definition of treatment failure

Chen 2005 China/ inpatients

2 years of continuous productive cough, FEV1/FVC post BD < 0.7, FEV1 < 80% predicted. No respiratory failure, diabetes or bronchial asthma

At least 2 of 3 symptoms: increased sputum or dyspnoea or purulent sputum

86/81

71

75/44

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg/d 10 days + 15 mg/d 5 days

Not known

Gomaa 2008 (abstract only)

FEV1 < 50% predicted, no respiratory acidosis

Not stated

42/Not known

Not stated

Not stated

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg 15 days

Outcome not reported

Leuppi 2013 Switzerland/5 sites

Age > 40 years, smoking history ≥ 20 pack‐years

At least 2 of the following: change in baseline dyspnoea, cough or sputum quantity/purulence

314/296

69

60/45

20

5 days: days 1 to 4 methylprednisolone 40 mg, days 2 to 5 oral prednisolone 40 mg

14 days: days 1 to 4 methylprednisolone 40 mg, days 2 to 14 oral 40 mg prednisolone

Received open‐label glucocorticoids during index exacerbation

Rahman 2004 (abstract only) Bangladesh/1 site

Not stated

Not stated

Not stated

Not stated

Not stated

Not stated

Prednisolone 30 mg 7 days

Prednisolone 30 mg 14 days

Outcome not reported

Salam 1998 (abstract only) USA/Unknown sites

Not stated

Not stated

21/Not known

Not stated

Not stated

None in previous month

IV CS 3 days

IV CS 3 days + 7 days OCS

Outcome not reported

Sayiner 2001 Turkey/1 site

FEV1 < 35% predicted, PYH > 20, no respiratory failure requiring ventilation

Not stated, requiring admission

36/34

65

94/Not stated

None in previous month

IV methylprednisone 0.5 mg/kg qds 3 days

IV methylprednisone 0.5 mg/kg qds 3 days, bd 3 days, od 4 days

Required open‐label steroid treatment

Sirichana 2008 (abstract and author data) Thailand/1 site

Age > 40 years, symptoms > 24 hours

Increase in at least 2 of 3 symptoms—dyspnoea, sputum volume, sputum purulence; requiring admission

48/42

73

88/Not stated

None in previous month

Prednisolone 30 mg 5 days

Prednisolone 30 mg 10 days

Outcome not reported

Wood‐Baker 1997 (abstract and author data) Australia & New Zealand/2 sites

Age > 40 years; > 10 pack‐year smoking history; FEV1 < 50% predicted

Not stated, requiring admission

38/28

71

63/Not stated

None for current AEs, no long‐term OS > 5 mg/d

Prednisolone 2.5 mg/kg orally daily for 3 days

Prednisolone 0.6 mg/kg orally daily for 7 days followed by prednisolone 0.3 mg/kg orally daily for 7 days

Lack of progress according to attending physician during treatment

Figures and Tables -
Table 1. Study characteristics
Table 2. Sensitivity analyses

Excluding Sirichana (not blinded)

All studies

Relapse

1.01 (0.66 to 1.55)

1.04 (0.70 to 1.56)

FEV1 early

‐0.09 (‐0.22 to 0.05)

‐0.07 (‐0.19 to 0.05)

FEV1 end

‐0.06 (‐0.23 to 0.11)

‐0.04 (‐0.19 to 0.10)

FVC early

‐0.00 (‐0.25 to 0.25)

0.01 (‐0.20 to 0.22)

FVC end

‐0.14 (‐0.38 to 0.09)

‐0.12 (‐0.33 to 0.09)

Adverse event—other

0.94 (0.48 to 1.82)

0.89 (0.46 to 1.69)

Excluding Sayiner (IV SCS)

All studies

Treatment failure

0.66 (0.32 to 1.37)

0.72 (0.36 to 1.46)

Relapse

1.02 (0.67 to 1.56)

1.04 (0.70 to 1.56)

Adverse event—hyperglycaemia

0.99 (0.63 to 1.54)

0.99 (0.64 to 1.53)

Adverse event—other

0.89 (0.46 to 1.69)

0.89 (0.46 to 1.69)

FEV1 early

‐0.02 (‐0.19 to 0.16)

‐0.07 (‐0.19 to 0.05)

FEV1 end

0.03 (‐0.06 to 0.12)

‐0.04 (‐0.19 to 0.10)

FVC early

0.12 (‐0.18 to 0.42)

0.01 (‐0.20 to 0.22)

FVC end

‐0.06 (‐0.34 to 0.22)

‐0.12 (‐0.33 to 0.09)

Figures and Tables -
Table 2. Sensitivity analyses
Comparison 1. Systemic corticosteroids for 7 or fewer days vs longer than 7 days

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Treatment failure Show forest plot

4

457

Odds Ratio (M‐H, Fixed, 95% CI)

0.72 [0.36, 1.46]

2 Relapse Show forest plot

4

478

Odds Ratio (M‐H, Fixed, 95% CI)

1.04 [0.70, 1.56]

3 Time to re‐exacerbation Show forest plot

1

Hazard Ratio (Fixed, 95% CI)

Subtotals only

4 Adverse effect—hyperglycaemia Show forest plot

2

345

Odds Ratio (M‐H, Fixed, 95% CI)

0.99 [0.64, 1.53]

5 Adverse effect—hypertension Show forest plot

1

Odds Ratio (M‐H, Fixed, 95% CI)

Subtotals only

6 Other adverse effects—gastrointestinal tract bleeding, symptomatic gastrointestinal reflux, symptoms of congestive heart failure or ischaemic heart disease, sleep disturbance, fractures, depression Show forest plot

5

503

Odds Ratio (M‐H, Fixed, 95% CI)

0.89 [0.46, 1.69]

7 Mortality Show forest plot

2

336

Odds Ratio (M‐H, Fixed, 95% CI)

0.91 [0.40, 2.06]

8 Length of hospitalisation Show forest plot

3

421

Mean Difference (IV, Fixed, 95% CI)

‐0.61 [‐1.51, 0.28]

9 FEV1 (L) (early) Show forest plot

3

96

Mean Difference (IV, Fixed, 95% CI)

‐0.07 [‐0.19, 0.05]

9.1 FEV1 absolute

2

75

Mean Difference (IV, Fixed, 95% CI)

‐0.08 [‐0.22, 0.06]

9.2 FEV1 change

1

21

Mean Difference (IV, Fixed, 95% CI)

‐0.04 [‐0.27, 0.19]

10 FEV1 % predicted (6 days) Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Subtotals only

11 FVC (L) (early) Show forest plot

3

97

Mean Difference (IV, Fixed, 95% CI)

0.01 [‐0.20, 0.22]

11.1 FVC measured

2

75

Mean Difference (IV, Fixed, 95% CI)

‐0.05 [‐0.29, 0.19]

11.2 FVC change from baseline

1

22

Mean Difference (IV, Fixed, 95% CI)

0.23 [‐0.23, 0.69]

12 FEV1 (L) end of treatment Show forest plot

4

187

Mean Difference (IV, Random, 95% CI)

‐0.04 [‐0.19, 0.10]

12.1 FEV1 measured

3

164

Mean Difference (IV, Random, 95% CI)

‐0.05 [‐0.25, 0.16]

12.2 FEV1 change from baseline

1

23

Mean Difference (IV, Random, 95% CI)

‐0.04 [‐0.23, 0.14]

13 FEV1 % predicted 30 days Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Subtotals only

14 FVC (L) end of treatment Show forest plot

3

99

Mean Difference (IV, Fixed, 95% CI)

‐0.12 [‐0.33, 0.09]

14.1 FVC measured

2

77

Mean Difference (IV, Fixed, 95% CI)

‐0.14 [‐0.39, 0.11]

14.2 FVC change from baseline

1

22

Mean Difference (IV, Fixed, 95% CI)

‐0.07 [‐0.44, 0.29]

15 PaO2 (mmHg) (early) Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Totals not selected

16 PaO2 (mmHg) end of treatment Show forest plot

2

121

Mean Difference (IV, Fixed, 95% CI)

‐1.38 [‐4.96, 2.21]

17 PaCO2 (mmHg) Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Totals not selected

17.1 3 days of follow‐up

1

Mean Difference (IV, Fixed, 95% CI)

0.0 [0.0, 0.0]

17.2 10 days of follow‐up

1

Mean Difference (IV, Fixed, 95% CI)

0.0 [0.0, 0.0]

18 Symptoms—dyspnoea (early) Show forest plot

2

320

Std. Mean Difference (IV, Fixed, 95% CI)

‐0.08 [‐0.29, 0.14]

19 Symptoms—dyspnoea (15 days) Show forest plot

4

404

Std. Mean Difference (IV, Fixed, 95% CI)

0.16 [‐0.03, 0.36]

19.1 Change

3

133

Std. Mean Difference (IV, Fixed, 95% CI)

0.25 [‐0.09, 0.60]

19.2 Absolute

1

271

Std. Mean Difference (IV, Fixed, 95% CI)

0.12 [‐0.12, 0.36]

20 Quality of life—overall (6 days) Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Subtotals only

21 Quality of life—overall (30 days) Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Subtotals only

Figures and Tables -
Comparison 1. Systemic corticosteroids for 7 or fewer days vs longer than 7 days