Abstract
A systematic review and Bayesian network meta-analysis is necessary to evaluate the efficacy and safety of triple therapy with different doses of inhaled corticosteroids (ICS) in stable chronic obstructive pulmonary disease (COPD). We selected 26 parallel randomized controlled trials (41,366 patients) comparing triple therapy with ICS/long-acting beta-agonist (LABA), LABA/long-acting muscarinic antagonist (LAMA), and LAMA in patients with stable COPD for ≥ 12 weeks from PubMed, EMBASE, the Cochrane Library, and clinical trial registries (search from inception to June 30, 2022). Triple therapy with high dose (HD)-ICS exhibited a lower risk of total exacerbation in pre-specified subgroups treated for ≥ 48 weeks than that with low dose (LD)-ICS (odds ratio [OR] = 0.66, 95% credible interval [CrI] = 0.52–0.94, low certainty of evidence) or medium dose (MD)-ICS (OR = 0.66, 95% CrI = 0.51–0.94, low certainty of evidence). Triple therapy with HD-ICS exhibited a lower risk of moderate-to-severe exacerbation in pre-specified subgroups with forced expiratory volume in 1 s < 65% (OR = 0.6, 95% CrI = 0.37–0.98, low certainty of evidence) or previous exacerbation history (OR = 0.6, 95% CrI = 0.36–0.999, very low certainty of evidence) than triple therapy with MD-ICS. Triple therapy with HD-ICS may reduce acute exacerbation in patients with COPD treated with other drug classes including triple therapy with LD- or MD-ICS or dual therapies.
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Introduction
Chronic obstructive pulmonary disease (COPD) is as an important chronic inflammatory airway disease, but its treatment is still challenging. As COPD is characterized by persistent airflow limitation, bronchodilators including long-acting beta-agonists (LABAs) and long-acting muscarinic antagonists (LAMAs) have been the main treatment modalities. While inhaled corticosteroid (ICS) therapy, a key therapy modality for asthmatics, was reported to be less effective in COPD treatment1,2,3,4, it has been reported that ICS-containing combination therapy is effective in COPD. Randomized controlled trials (RCTs) have shown that combination therapy with ICS/LABA reduces the risk of acute exacerbation5,6. Currently, it is evident that triple therapy with ICS/LABA/LAMA has the best efficacy in terms of reducing acute exacerbation and mortality as well as improving symptoms and lung function among drug classes, especially among those with previous exacerbation history and elevated blood eosinophil counts7,8,9.
However, the ICS dose for triple therapy in patients with COPD has not been determined. ICS is associated with an increased risk of pneumonia10,11. The increased risk of pneumonia due to ICS has been reported primarily in studies using triple therapy with high dose (HD)-ICS12; low dose (LD)-ICS triple therapy was not associated with pneumonia risk13. Thus, there are concerns about using higher dose ICS-containing regimens13. Furthermore, a ceiling efficacy has been reported for ICSs. In asthmatics, the maximum level of efficacy was usually reached with LD-ICS, while HD-ICS did not show additional benefit14,15. This suggests that a high dose-ICS is not beneficial considering risk and benefit. However, a recent network meta-analysis (NMA) with triple therapy in uncontrolled asthma reported that HD-ICS showed superiority in reducing moderate-to-severe exacerbation and improving forced expiratory volume in one second (FEV1) compared to triple therapy with medium dose (MD)-ICS16. For patients with COPD, only one RCT has reported that there were no significant differences in the risk of exacerbation and mortality between triple therapy with MD-ICS and that with LD-ICS17. The ICS dose with the best efficacy and safety and the patient stratification parameters for guiding ICS dose determination in triple therapy are unclear.
Therefore, we conducted a systematic review (SR) and NMA to compare triple therapies with LD-, MD-, and HD-ICS with reference to efficacy (including exacerbation and mortality) and safety; we also sought to identify specific subgroups which may derive benefit from specific ICS dose levels.
Results
Study selection and network structure
We identified a total of 2871 records from the pre-specified databases (Fig. 1). After the removal of 1237 duplicate records, 1634 records were screened to find 55 relevant articles or abstracts for retrieval. Among the nine records identified from other sources, one report was not accessible and seven reports did not meet the eligibility criteria. After the full-text review, 26 studies met the eligibility criteria of the present SR. Supplementary information 1 includes a summary of the excluded references and the major reasons for the exclusion. A network geometry of the included RCTs is graphically described for total and moderate-to-severe exacerbation in Fig. 2. Direct head-to-head comparison between triple therapies with different ICS doses was found in four studies, all of which compared MD-ICS and LD-ICS.
Study characteristics
Detailed information on the 25 published and one unpublished eligible RCTs conducted between 2007 and 2022 and the 41,366 participants included in those RCTs are summarized in Table 1. After the full-text review, 26 studies from 23 references17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39 met the eligibility criteria. A direct head-to-head comparison between triple therapies with different ICS doses was found in four studies, all of which compared MD-ICS and LD-ICS17,23,24. The mean age was 64.7 years, the proportion of men was 68.4%, and the proportion of current smokers was approximately 40.7%. In 14 RCTs with information on ethnicity, the predominant ethnicities were white/Caucasian and Asian. Patients with moderate-to-very severe COPD were included and their mean post-bronchodilator FEV1% was 43.8%. The distribution of the Global Initiative for Chronic Obstructive Lung Disease (GOLD) grades was as follows: grades 3–4, 40,917 (37.9%) patients; grades 2–4, 39,403 (36.5%) patients; and grades 2–3, 27,536 (25.5%) patients. HD-ICS was used in five RCTs18,19,20,21,22, MD-ICS in 15 RCTs17,23,24,25,26,27,28,29,30,31,32,33,34, and LD-ICS in 10 RCTs17,23,24,35,36,37,38,39.
Risk of bias (ROB) within and across studies
As per the assessment of ROB within studies, the quality of the included RCTs was considered to be generally acceptable for the NMA (Supplementary information 2). Detailed information on ROB assessment is summarized in Supplementary information 3. In the assessment of ROB across studies, we could not find either significant publication bias or selective reporting bias (Supplementary information 4).
Certainty of evidence
The certainty of evidence is described in Supplementary information 5.
Acute exacerbations and mortality
The risk of total exacerbation was compared among inhaled therapies in 23 RCTs with 39,682 participants (Table 2). Among the drug classes, the highest surface under the cumulative ranking curve (SUCRA) was observed for triple therapy with HD-ICS. Triple therapy with HD-ICS exhibited a significantly lower risk of total exacerbation compared with LABA/LAMA, MD-ICS/LABA, LD-ICS/LABA, and LAMA. Triple therapy with MD-ICS exhibited a significantly lower risk of total exacerbation than MD-ICS/LABA. Triple therapy with LD-ICS exhibited a significantly lower risk of total exacerbation than MD-ICS/LABA and LD-ICS/LABA. In the pre-specified sensitivity analyses, triple therapy with HD-ICS showed significant superiority in reducing total exacerbation compared to triple therapy with LD- or MD-ICS in the subgroups with a study duration of ≥ 48 weeks (HD-ICS vs. LD-ICS, OR = 0.66 [95% credible interval (CrI) = 0.52–0.94], low certainty of evidence; HD-ICS vs. MD-ICS, OR = 0.66 [95% CrI = 0.51–0.94], low certainty of evidence) (Supplementary information 6).
The risk of moderate-to-severe exacerbation was compared among the inhaled therapies in 12 RCTs with 33,545 participants (Table 2). Triple therapy with HD-ICS exhibited the highest SUCRA among the drug classes, and conferred a significantly lower risk of moderate-to-severe exacerbation than LABA/LAMA, MD-ICS/LABA, LD-ICS/LABA, and LAMA. Triple therapy with MD-ICS exhibited a significantly lower risk of moderate-to-severe exacerbation than MD-ICS/LABA. Triple therapy with LD-ICS exhibited a significantly lower risk of moderate-to-severe exacerbation than MD-ICS/LABA. In the pre-specified sensitivity analyses, triple therapy with HD-ICS was also superior to triple therapy with MD-ICS in subgroups with FEV1 < 65% (OR = 0.6 [95% CrI = 0.37–0.98], low certainty of evidence) or at least 1 exacerbation event in the past year (OR = 0.6 [95% CrI = 0.36–0.999], very low certainty of evidence) (Supplementary information 7).
The risk of all-cause mortality was compared among different inhaled therapies in 24 RCTs with 41,004 participants (Table 2). Triple therapy with MD-ICS exhibited the highest SUCRA. Triple therapy with MD-ICS was associated with a significantly lower risk of all-cause mortality compared to LABA/LAMA (OR = 0.62 [95% CrI = 0.42–0.92], high certainty of evidence). There was no significant finding in the pre-specified sensitivity analyses for all-cause mortality (Supplementary information 8).
Lung function and symptoms
The mean change in trough FEV1 was compared among the inhaled therapies in 17 RCTs with 24,823 participants (Table 3). Triple therapy with LD-ICS exhibited the highest SUCRA among the drug classes. Triple therapy with MD-ICS was associated with a significantly improved FEV1 compared to HD-ICS/LABA, MD-ICS/LABA, LD-ICS/LABA, and LAMA. Triple therapy with LD-ICS led to a significantly improved FEV1 compared to that with LABA/LAMA, HD-ICS/LABA, MD-ICS/LABA, LD-ICS/LABA, and LAMA. In the pre-specified sensitivity analyses, triple therapy with HD-ICS was superior to LD-ICS/LABA in terms of improving trough FEV1 in the subgroups with study duration < 24 or < 48 weeks (Supplementary information 9).
The mean change in the St. George's Respiratory Questionnaire (SGRQ) score was compared among the inhaled therapies in 19 RCTs with 30,404 participants (Table 3). Triple therapy with LD-ICS exhibited the highest SUCRA among the drug classes. Triple therapy with HD-ICS showed a significantly decreased SGRQ compared to HD-ICS/LABA and LAMA. Triple therapy with MD-ICS exhibited a significantly decreased SGRQ compared to LABA/LAMA, HD-ICS/LABA, MD-ICS/LABA, and LAMA. Triple therapy with LD-ICS showed a significantly decreased SGRQ compared to LABA/LAMA, HD-ICS/LABA, MD-ICS/LABA, LD-ICS/LABA, and LAMA. In the pre-specified sensitivity analyses, triple therapy with MD-ICS was superior to LD-ICS/LABA in terms of improving SGRQ scores in the subgroups with FEV1 < 65%, at least one exacerbation history in the past year, or more symptoms (COPD Assessment Test (CAT) ≥ 10 or modified Medical Research Council (mMRC) ≥ 2) (Supplementary information 10).
Adverse events
The risk of serious adverse events was compared among different inhaled therapies in 25 RCTs with 41,623 participants (Table 4). Triple therapy with MD-ICS was associated with a lower risk of serious adverse events compared to LABA/LAMA or MD-ICS/LABA. There was no significant finding in the pre-specified sensitivity analyses for serious adverse events (Supplementary information 11).
The risk of serious cardiac adverse events was compared among different inhaled therapies in 23 RCTs with 40,552 participants (Table 4). Triple therapy with MD-ICS was associated with a lower risk of serious cardiac adverse events compared to LABA/LAMA. We incidentally found that MD-ICS/LABA was associated with a lower risk of serious cardiac adverse events compared to LABA/LAMA. There was no significant finding in the sensitivity analyses for serious cardiac adverse events (Supplementary information 12).
The risk of pneumonia was compared among different inhaled therapies in 25 RCTs with 41,713 participants (Table 4). The risk of pneumonia was higher with triple therapy with MD-ICS (OR = 1.47 [95% CrI = 1.004–2.01], moderate certainty of evidence) or LD-ICS (OR = 1.50 [95% CrI = 1.06–2.04], high certainty of evidence) than with LABA/LAMA. There was no significant finding in the pre-specified sensitivity analyses for pneumonia (Supplementary information 13).
Consistency assumption
The consistency assumption was satisfied between the estimated effect size in the paired meta-analysis via direct comparisons and the estimated effect size by Bayesian NMA via indirect comparisons. Detailed information is summarized in Supplementary information 14.
Discussion
Our study investigated the differences in the efficacy and safety of triple therapy with varying ICS doses used for > 12 weeks in patients with COPD. Although there was no significant difference in the analysis including all eligible studies, triple therapy with HD-ICS showed superiority in reducing total or moderate-to-severe exacerbation compared to triple therapy with LD- or MD-ICS in sensitivity analyses, with a low certainty of evidence. Triple therapy with MD-ICS was associated with the lowest risk of all-cause mortality and serious adverse events, and triple therapy using LD-ICS showed the highest efficacy in improving SGRQ scores and FEV1 based on SUCRA, although there were no significant differences among the triple therapies in this regard. Pneumonia risk was comparable among the triple therapies with different ICS doses.
The optimal ICS dose for patients with COPD has been debated upon by various researchers. Our study provides low certainty of evidence supporting the contention that triple therapy with HD-ICS is a better option for reducing exacerbation than triple therapies with MD- or LD-ICS. In patients with difficult-to-treat or severe asthma, high-dose ICS is often required to control symptoms or reduce exacerbation40. In chronic airway diseases, neutrophilic airway inflammation is considered to be an important mechanism underlying a reduced response to ICS41. COPD is characterized by chronic airway inflammation caused by an increase in the number and activation of neutrophils42. Neutrophilic airway inflammation can reduce the response to ICS through the dysregulation of the glucocorticoid receptor and impairment of mitogen-activated protein kinase phosphatase 1 function43,44. Considering that neutrophilic airway inflammation is related to the severity of COPD45,46, a higher dose of ICS is likely to be more effective because a majority of patients with COPD who need triple therapy would have elevated airway inflammation. In addition, considering that increased airway inflammation underlies acute exacerbation of chronic obstructive pulmonary disease (AE-COPD)47, decreased activation of inflammatory cells and pro-inflammatory cytokines would be one of the plausible mechanisms for the reduced exacerbation observed with HD-ICS (triple therapy) in the COPD subgroups48. Synergistic anti-inflammatory effects of ICS, LABA, and LAMA may further reduce acute exacerbation in triple therapy49. It has been reported that a ceiling efficacy (maximal efficacy) can be achieved with LD-ICS, and that HD-ICS may not show additional benefit. However, the synergism of triple combination therapy may attenuate the ceiling effect observed with HD-ICS14,15. LABA and LAMA have a synergistic effect on bronchodilation and act by inhibiting acetylcholine release from airway epithelium; they also exert anti-inflammatory action through the inactivation of inflammatory signaling pathways50. Through the complementary/additive effects of LABA and ICS, the anti-inflammatory and anti-remodeling activity of ICS can be enhanced, even when there is no further benefit from increasing the ICS dose51,52. Synergistic interactions between ICS and LAMA lead to increased cAMP, which further leads to bronchorelaxation and decreases airway inflammation49. Recently, triple therapy also exhibited a synergistic effect with reference to small airway relaxation compared to ICS/LABA53. In summary, additional anti-inflammatory activity due to synergistic effects of the components of triple therapy with HD-ICS may explain the reduced exacerbation observed in this study. However, dose-dependence of the ICS responses in triple therapy need further clarification.
Although there was no significant difference in the associated mortality risk among the triple therapies with different ICS doses, only triple therapy with MD-ICS showed superiority in reducing all-cause mortality compared to LABA/LAMA. In addition, only triple therapy with MD-ICS was able to show a higher reduction in serious adverse events/serious cardiac adverse events compared to LABA/LAMA. Cardiovascular events are among the major causes of death in COPD54. Previous observational studies showed that ICS may exert a cardioprotective effect55. Our results suggest that physicians should consider triple therapy with MD-ICS in patients with cardiovascular comorbidity or history of serious adverse events, especially among those treated with LABA/LAMA.
Various studies have reported on the improvement of lung function or health-related quality of life by ICS. Although the use of ICS led to lung function improvement in the SUMMIT56 and TORCH57 trials and SGRQ improvement in the IMPACT trial37, there is no consensus on whether the improvement was clinically meaningful. A recent paired meta-analysis revealed that triple therapy improved both FEV1 and SGRQ compared to LABA/LAMA with statistical and clinical significance58. In our study, there was no significant difference in the improvement of lung function and SGRQ according to the ICS dose among the triple therapies. However, triple therapy with LD-ICS exhibited the highest SUCRA and significantly improved FEV1 and SGRQ compared to LABA/LAMA, ICS/LABA, or LAMA. Therefore, adding LD-ICS to LABA/LAMA may have the benefit of improving FEV1 or SGRQ in patients with COPD who need triple therapy.
Many studies have evaluated the dose-dependence of ICS-related adverse events in COPD. A higher dose of ICS conferred a significantly higher risk of hospitalization for pneumonia59. In addition, a higher dose of ICS was related to tuberculosis60, diabetes61, bone fracture62, and cataract63. However, the risk of adverse events according to ICS dose among triple therapies has not been well evaluated. In our study, escalation to triple therapy with HD-ICS did not increase the risk of pneumonia. Interestingly, we found that triple therapy with MD-ICS significantly increased the risk of pneumonia but reduced the incidence of serious cardiac adverse events compared to LABA/LAMA. Overall, there were significantly fewer serious adverse events with triple therapy with MD-ICS than with LABA/LAMA. This result can be explained by the findings from a previous investigation in which most ICS-related pneumonias were reported to be of low severity64.
The strengths of the present study are as follows. First, to our knowledge, this is the first SR and NMA to compare triple therapies according to ICS doses in patients with stable COPD. Second, we performed a novel and extensive SR and NMA by reviewing 2,880 articles including unpublished data and the latest clinical trials. Third, we used Bayesian methods for performing pertinent comparisons of rare events such as mortality or serious cardiac adverse events65. Bayesian NMA is a useful method to estimate the comparative efficacy of different treatments when head-to-head RCTs are insufficient. Bayesian NMA provides the probability of the best treatment or SUCRA among different treatments for each outcome. This approach can be more useful for clinicians in decision-making situations than a p-value66.
There were several limitations to our study. First, clinical heterogeneity regarding symptom severity, previous exacerbation history, and baseline lung function was found among the included RCTs, although statistical or methodological heterogeneity was not significant. Second, our study pooled data primarily from the study populations that benefited from triple therapy. Therefore, our results should be applied to patients with COPD who are expected to have additional benefit from triple therapy. For example, adding LD-ICS to LABA/LAMA for FEV1 or SGRQ improvement in patients with COPD without exacerbation history is a misinterpretation of the results. Third, we arbitrarily classified ICS doses into low, medium, and high based on the reference for asthma patients. As there has been no official consensus for ICS dose classification in COPD, several studies have classified ICS doses in patients with COPD based on the guidelines as per the Global Initiative for Asthma (GINA) report67. Further study is necessary to evaluate the efficacy and safety of different doses of ICS in patients with COPD. Fourth, since 2016, there have been few studies evaluating triple therapy with HD-ICS, and the number of related studies is relatively small. For a more definitive conclusion, further research on triple therapy with HD-ICS is needed. Fifth, sensitivity analyses according to blood eosinophil counts were not performed because the range of the mean blood eosinophil counts was narrow (150–250/μL), and sufficient networks could not be generated among the different ICS doses.
Conclusion
There were no significant differences in efficacy and safety among triple therapies with different ICS doses. Among patients with COPD, triple therapy with HD-ICS may reduce exacerbation in specific subgroups (treatment duration ≥ 48 weeks, FEV1 < 65%, and previous exacerbation history) with a low certainty of evidence.
Methods
Protocol and pre-registration
We drafted the study protocol as per the Preferred Reporting Items for Systematic Review and Meta-Analysis (PRISMA) extension statement for the reporting of SRs incorporating NMAs on healthcare interventions68, and also referred to the updated PRISMA 2020 statement69. We followed the BayesWatch guidelines for reporting our results obtained using Bayesian statistics70. The study protocol was previously registered on the international prospective register of systematic reviews (CRD42021259602, PROSPERO).
Eligibility criteria
Eligible studies met the following inclusion criteria: (1) parallel-design RCTs on COPD with information on acute exacerbation as a prespecified outcome; (2) including patients with stable COPD aged > 40 years; (3) inhaled treatment with triple therapy or ICS/LABA/LAMA; and (4) treatment duration of at least 12 weeks.
Study outcome
The primary outcome was total and moderate-to-severe exacerbation events in patients who used triple therapy with different ICS doses. We defined LD-, MD-, and HD-ICS according to the guidelines as per the GINA report71. The secondary outcome was all-cause mortality, change in morning trough FEV1 and SGRQ, and safety profiles including serious adverse events, serious cardiac adverse events, and pneumonia.
Sensitivity and subgroup analyses were conducted to identify specific subpopulations in patients with COPD with different efficacy or safety profiles for reducing moderate-to-severe or total exacerbations according to baseline lung function, previous exacerbation history, severity of dyspnea (CAT ≥ 10 or mMRC score ≥ 2), mean blood eosinophil count, and study duration.
Information sources
We searched for relevant articles or abstracts that were registered in PubMed, EMBASE, and the Cochrane Library. To obtain more information on unpublished data, we searched the European Union (EU) Clinical Trial Register, the United States (US) National Library of Medicine, and the websites of several pharmaceutical companies including AstraZeneca, Boehringer Ingelheim, GlaxoSmithKline, and Novartis. We contacted the corresponding author or the person in charge for each study to request undisclosed information. We manually searched previously published SRs for relevant references.
Search strategy
Our search strategy was formulated based on the Peer Review of Electronic Search Strategies checklist (search date: June 30, 2022)72. Controlled vocabularies and free texts were used to create the queries. The following keywords were used: “COPD” AND inhaled drugs (“ICS” AND “LABA” AND “LAMA”) AND randomized controlled design. Detailed information on the search strategy is described in Supplementary information 15 and the pre-registered study protocol.
Study selection
Two independent authors (H.W.L. and H.M.P.) performed the process for selecting eligible RCTs in accordance with the currently updated PRISMA flow diagram69. The two authors individually checked duplicated literature with the same data source, screened the titles and abstracts to find potentially eligible studies, and fully reviewed the manuscript to finally select studies in concordance with the eligibility criteria. We resolved any disagreements during the study selection process by referring to the original article and discussing it with the third author (C.H.L.).
Data collection
Before initiating the data extraction process, we obtained a consensus (among the authors)on the methodology for evaluating the quality of the eligible studies and that for the synthesis of the outcome variables. After a pilot format for data extraction was structured, pilot-tested, and refined, the data extraction process was independently conducted by two authors (H.W.L. and H.M.P.). Any disagreements regarding the extracted data were resolved by referring to the original manuscript and discussion with a third author (C.H.L.).
The following data items were extracted: (1) study-level baseline information (first author, published year, trial identifier, study duration, inclusion and exclusion criteria, the number of subjects included in intention-to-treat analysis, and pre-specified study objectives); (2) patient-level baseline information (age, sex, smoking history, and ethnicity); (3) clinical information (mean post-bronchodilator FEV1, COPD severity [GOLD stage], history of moderate or severe exacerbation of COPD, and severity of symptoms [mMRC or CAT score]); and (4) outcome information (the number of patients with acute exacerbations of COPD or mortality events, change in FEV1 or SGRQ, the number of patients with serious adverse events, serious cardiac adverse events, or pneumonia until the last follow-up). Digitizing the raw data from the Kaplan–Meier curve was allowed73. We defined the severity of acute COPD exacerbation based on Exacerbations of Chronic Pulmonary Disease Tool or the use of healthcare resources74,75. The definition of moderate exacerbation was as follows: worsening respiratory symptoms that required systemic corticosteroids or antibiotics. The definition of severe exacerbation was as follows: worsening respiratory symptoms that required hospitalization or visit to the emergency room. Serious adverse events were defined based on the Office for Human Research Protections guidelines, as follows: any condition resulting in death, life-threatening status, hospitalization or prolonged hospitalization, significant disability or incapacity, and congenital defects based on physician’s judgment76. As the majority of the included studies did not report major adverse cardiovascular events with sufficient clarity, serious cardiac adverse events were evaluated. Serious cardiovascular events were defined as ≥ 3 grade cardiovascular events based on the Common Terminology Criteria for Adverse Events77.
Network geometry
The geometry of the treatment network was explored to identify the following: the number of triple therapies classified as low, medium, or high ICS dose therapies; the inhaled drugs that were directly compared; the number of patients assigned to receive each inhaled drug; the inhaled drugs or comparisons that were either preferred or avoided. To depict the geometry of the network, we expressed each individual inhaled drug or combination therapy as a node and each comparison between two different interventions as an edge between nodes. The number of direct comparisons between two different interventions was described as the thickness of the edge and expressed at the middle of the edges.
ROB assessment within and across individual studies
The ROB at the individual study level was independently assessed by two reviewers (H.W.L. and H.M.P.) using the Cochrane ROB78 and ROB 2 tool79. Publication bias was used as a metric for the assessment of ROB across studies; we used funnel plots and Egger’s tests to detect publication bias. We tested for selective reporting by referring to the pre-registered study protocol. Any disagreements related to the assessment of ROB was resolved by discussion with the other authors.
Summary measures and analysis method
A random effects model was optimized with a heterogeneous variance structure for the present NMA, because the variances of the efficacy and safety outcomes were assumed to be different among triple therapies with different ICS doses80,81. We adopted non-informative prior distributions assuming the existence of a normal or uniform distribution82. Triple therapies with different ICS doses were ranked based on the probability of the best treatment using the SUCRA methodology83. The median posterior ORs with 95% CrIs for categorical outcomes and the median posterior mean difference with 95% CrIs for continuous outcomes were derived from the posterior distributions. Statistical significance was determined if the 95% CrIs did not include 1.0 for an OR and zero for a mean difference. For direct comparisons among inhaled therapies, pairwise meta-analyses were conducted with a random effects model.
We used the “gemtc” and “BUGSnet” packages in R software, version 4.0.5 [R Core Team (2018), Vienna, Austria] to simulate the posterior probability distribution of each parameter using the Markov Chain Monte Carlo (MCMC) method. We checked the convergence of the results from the MCMC simulations using trace plots, autocorrelation plots, and Gelman-Rubin statistics.
Testing of assumptions
The homogeneity and transitivity assumptions were assessed by reviewing the inclusion criteria of the included RCTs and baseline characteristics of the included study subjects. The consistency assumption was assessed by using the node-splitting method84. The heterogeneity across studies was assessed using the posterior median value of the standard deviation (SD) between studies85,86. We appraised the transitivity assumption by checking whether all the treatment options in the network were randomized by reviewing the inclusion criteria in the included studies87.
Certainty of evidence
We rated the quality of evidence based on five domains (ROB, inconsistency, indirectness, imprecision, and publication bias) using the GRADE (Grading of Recommendations, Assessment, Development, and Evaluations) guidelines.
Data availability
The datasets generated and/or analyzed during the current study are not publicly available due the fact that the journals the published the included studies have the copyrights for the information used in our meta-analysis, but are available from the corresponding author on reasonable request.
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Study concept and design: H.W.L. and C.H.L. Acquisition of data: H.W.L., H.M.P., and C.H.L. Analysis and interpretation of data: H.W.L., E.J.J., and C.H.L. Manuscript drafting: H.W.L., E.J.J., and C.H.L. Critical revision of the manuscript and important intellectual content: E.J.J. and C.H.L. Study supervision: C.H.L. The corresponding author attests that all listed authors meet authorship criteria and that no others meeting the criteria have been omitted.
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Lee, H.W., Park, H.M., Jang, E.J. et al. Different inhaled corticosteroid doses in triple therapy for chronic obstructive pulmonary disease: systematic review and Bayesian network meta-analysis. Sci Rep 12, 15698 (2022). https://doi.org/10.1038/s41598-022-18353-y
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DOI: https://doi.org/10.1038/s41598-022-18353-y
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