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. 2021 Apr 30;38(6):3089–3112. doi: 10.1007/s12325-021-01703-z

Efficacy and Safety of Budesonide/Glycopyrronium/Formoterol Fumarate versus Other Triple Combinations in COPD: A Systematic Literature Review and Network Meta-analysis

Arnaud Bourdin 1,8,, Nicolas Molinari 2, Gary T Ferguson 3, Barinder Singh 4, Mohd Kashif Siddiqui 5, Ulf Holmgren 6, Mario Ouwens 6, Martin Jenkins 7, Enrico De Nigris 7
PMCID: PMC8189959  PMID: 33929661

Abstract

In patients with chronic obstructive pulmonary disease (COPD) who experience further exacerbations or symptoms, despite being prescribed dual long-acting muscarinic antagonist (LAMA)/long-acting β2-agonist (LABA) or inhaled corticosteroid (ICS)/LABA therapies, triple ICS/LAMA/LABA therapy is recommended. A previous network meta-analysis showed comparable efficacy of the ICS/LAMA/LABA, budesonide/glycopyrronium bromide/formoterol fumarate (BUD/GLY/FOR) 320/18/9.6 µg, to other fixed-dose and open combination triple therapies at 24 weeks in COPD. Subsequently, the ETHOS study was published, including data for 8509 patients, assessing the efficacy and safety of BUD/GLY/FOR over 52 weeks. This network meta-analysis (NMA) was conducted to compare the relative efficacy, safety, and tolerability of BUD/GLY/FOR 320/18/9.6 µg with other fixed-dose and open combination triple therapies in COPD over 52 weeks, including data from ETHOS. A systematic literature review was conducted to identify ≥ 10-week randomized controlled trials, including ≥ 1 fixed-dose or open combination triple-therapy arm, in patients with moderate-to-very severe COPD. The methodologic quality and risk of bias of included studies were assessed. Study results were combined using a three-level hierarchical Bayesian NMA model to assess efficacy and safety outcomes at or over 24 and 52 weeks. Meta-regression and sensitivity analyses were used to assess heterogeneity across studies. Nineteen studies (n = 37,741 patients) met the inclusion criteria of the review; 15 contributed to the base case network. LAMA/LABA dual combinations were combined as a single treatment group to create a connected network. Across all outcomes for exacerbations, lung function, symptoms, health-related quality of life, safety, and tolerability, the efficacy and safety of BUD/GLY/FOR were comparable to those of other triple ICS/LAMA/LABA fixed-dose (fluticasone furoate/umeclidinium/vilanterol and beclomethasone dipropionate/glycopyrronium bromide/formoterol fumarate) and open combinations at or over 24 and 52 weeks. Sensitivity analyses and meta-regression results for exacerbation outcomes were broadly in line with the base case NMA. In this NMA, BUD/GLY/FOR 320/18/9.6 μg showed comparable efficacy versus other ICS/LAMA/LABA fixed-dose or open combination therapies in terms of reducing exacerbation rates and improving lung function, symptoms and health-related quality of life in patients with moderate-to-very-severe COPD, in line with previously published meta-analysis results of triple combinations in COPD. The safety and tolerability profile of BUD/GLY/FOR was also found to be comparable to other triple combination therapies.

Supplementary Information

The online version contains supplementary material available at 10.1007/s12325-021-01703-z.

Keywords: Chronic obstructive pulmonary disease, Exacerbations, Inhaled corticosteroid, Long-acting muscarinic antagonist, Long-acting β2-agonist, Lung function, Network meta-analysis, Patient-reported outcomes, Safety, Triple therapy

Key Summary Points

In patients with chronic obstructive pulmonary disease (COPD) who experience further exacerbations or symptoms, despite being prescribed dual long-acting muscarinic antagonist (LAMA)/long-acting β2-agonist (LABA) or inhaled corticosteroid (ICS)/LABA therapies, triple ICS/LAMA/LABA therapy is recommended
The clinical efficacy, safety and tolerability of budesonide/glycopyrronium bromide/formoterol fumarate (BUD/GLY/FOR), delivered via metered dose Aerosphere inhaler, was compared with other triple ICS/LAMA/LABA therapies (in available open or fixed-dose combinations) over 52 weeks in patients with moderate-to-very-severe COPD
BUD/GLY/FOR 320/18/9.6 μg showed comparable efficacy versus other ICS/LAMA/LABA open or fixed-dose combination therapies in terms of reducing exacerbation rates and improving lung function, symptoms and health-related quality of life in patients with moderate-to-very severe COPD, in line with previously published meta-analysis results of triple combinations in COPD
The safety and tolerability profile of BUD/GLY/FOR 320/18/9.6 μg was also comparable to other triple combination therapies

Digital Features

This article is published with digital features, including a summary slide, to facilitate understanding of the article. To view digital features for this article go to 10.6084/m9.figshare.14186543.

Introduction

Chronic obstructive pulmonary disease (COPD) is a progressive disease that leads to airflow limitation and persistent respiratory symptoms and is characterized by exacerbations and commonly presents with multiple comorbidities [1]. The goals of pharmacologic treatments in COPD include reducing symptoms, lowering the risk of exacerbations and reducing the impact an exacerbation might have on a patient with COPD [1]. Patients who have eosinophil counts ≥ 100 cells/µl, continuing exacerbations or remain symptomatic despite treatment with dual bronchodilator (long-acting β2-agonist [LABA]/long-acting muscarinic antagonist [LAMA]) or inhaled corticosteroid (ICS)/LABA combinations, are recommended by the Global Initiative for Obstructive Lung Disease (GOLD) to step up to triple therapy (ICS/LAMA/LABA) [1]. The component parts of triple therapy may be delivered as an ‘open’ combination in separate devices [24] or as a fixed-dose combination (FDC) within a single inhaler [58]. To date, there are no head-to-head randomized controlled trials (RCTs) of their relative efficacy in patients with COPD.

In lieu of head-to-head evidence, network meta-analyses (NMA) comparing the efficacy of triple therapy as a class with LAMA/LABA dual therapy or bronchodilator monotherapy have previously been presented [911]. Additionally, pairwise meta-analyses have compared triple therapies with ICS/LABA [12, 13] or LAMA/LABA therapies [13].

The ICS/LAMA/LABA budesonide/glycopyrronium bromide/formoterol fumarate (BUD/GLY/FOR), delivered via a metered dose Aerosphere inhaler, is a triple FDC that has been approved for the maintenance treatment of COPD in the US, Europe, China and Japan [1417]. In the Phase III ETHOS (NCT02465567) and KRONOS (NCT02497001) studies, BUD/GLY/FOR showed benefits in reducing COPD exacerbations and improving lung function and symptoms versus dual LAMA/LABA and ICS/LABA therapies [18, 19]. A recent NMA showed that BUD/GLY/FOR had similar efficacy to other ICS/LAMA/LABA fixed-dose and open combination therapies in reducing exacerbation rates, and improving lung function and symptoms at 24 weeks, in patients with moderate-to-very-severe COPD [20]. Subsequently, the recent ETHOS study has provided a large body of evidence regarding the efficacy and safety of BUD/GLY/FOR over 52 weeks [19], allowing for comparisons with other triple therapies that have been assessed in 1-year studies.

Therefore, the objective of this systematic literature review and NMA was to compare the relative clinical efficacy, safety and tolerability of BUD/GLY/FOR with other triple ICS/LAMA/LABA therapies over 52 weeks in patients with moderate-to-very-severe COPD, including data from the recent ETHOS study.

Methods

Systematic Literature Review

A systematic literature review was conducted to identify evidence on the efficacy, safety and tolerability of triple ICS/LAMA/LABA open or FDC therapies in patients with moderate-to-very-severe COPD. Open combinations were included as they are a widely available treatment option, and patients currently receiving open triple therapy may be candidates to switch to a triple FDC. The systematic literature review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines.

Searches of Embase®, MEDLINE®, MEDLINE® In-Process and the Cochrane Central Register of Controlled Trials (CENTRAL) were run from database inception to June 2020. Only articles published in English were included. The search strategies are shown in Table S1. Abstracts from the American Thoracic Society, European Respiratory Society and American College of Chest Physicians conference proceedings were hand searched from 2017 to retrieve studies that have not yet been published in full-text articles or abstracts reporting supplementary results of previously published studies.

Primary eligibility criteria were RCTs of duration ≥ 10 weeks, assessing patients ≥ 40 years of age with a clinical diagnosis of moderate-to-severe COPD (Table 1). Additionally, for inclusion, studies were required to compare one of the interventions with at least one of the comparators listed in Table 1.

Table 1.

Participants, interventions, comparisons, outcomes and study design criteria for inclusion in the network meta-analysis

Studies to include
Study designs Randomized controlled trials (including crossover studies up to the time of crossover)
Population

Age: adults (≥ 40 years old)

Gender: any

Race: any

Disease: moderate-to-very-severe COPD

Interventions Triple therapies (ICS + LAMA + LABA, both open and fixed combinations including BUD/GLY/FOR, BDP/GLY/FOR, FF/UMEC/VIL and other open triple combinations)
Comparators

Any included intervention

Dual therapies (ICS + LABA or LAMA + LABA in both open and closed combinations)

Monotherapies (ICS, LAMA or LABA)

Placebo/best supportive care/observation

Outcomes Efficacy and quality of life outcomes
 Lung function (post-bronchodilator FEV1, trough FEV1, AUC FEV1)
 Symptoms/dyspnea (TDI focal score, use of rescue medication)
 Exacerbations (moderate-to-severe or severe)
 HRQoL measurements (SGRQ, EQ-5D-5L)
Safety outcomes
 Any adverse events
 Any serious adverse events
 Any treatment-related adverse events
 Pneumonia
 Upper respiratory tract infections
Tolerability outcomes
 All withdrawals
 Withdrawal due to death
 Withdrawal due to adverse events
 Withdrawal due to lack of efficacy
Language English language studies
Publication timeframe Database: March 2017 to July 2020
Data sources
Databases

Embase®

MEDLINE®

MEDLINE® In-Process

CENTRAL

Conference search

American Thoracic Society

European Respiratory Society

American College of Chest Physicians

Other sources

ClinicalTrials.gov of the US National Institute of Health

Bibliographic searching using the relevant systematic literature reviews

AUC area under the curve, CENTRAL Cochrane Central Register of Controlled Trials, COPD chronic obstructive pulmonary disease, Embase Excerpta Medica Database, EQ-5D-5L 5-level EuroQol 5-dimensional questionnaire, FEV1 forced expiratory volume in 1 s, HRQoL health-related quality of life, ICS inhaled corticosteroids, LABA long-acting β2-agonist, LAMA long-acting muscarinic antagonist, MEDLINE Medical Literature Analysis and Retrieval System Online

The titles and abstracts of the publications identified in the search were screened, full-text copies of articles judged to be potentially relevant were reviewed, and data for eligible studies were extracted using a pre-defined extraction grid, which included details on trial design, inclusion criteria, study population characteristics, interventions, outcome measures and length of follow-up. Screening, review and data extraction were conducted by two independent reviewers, with results checked and reconciled by a third independent reviewer. Where a single study was described by more than one publication, the data were compiled into a single entry in the data extraction sheet to avoid duplication.

The methodologic quality of the included studies was assessed using the concise critical appraisal checklists provided by the National Institute for Health and Care Excellence (NICE) in the single technology appraisal user guide [21]. The risk of bias was assessed with respect to method of randomization and allocation concealment, comparability of baseline characteristics, blinding, balance of withdrawals between groups, outcomes reporting and statistical analysis.

Network Meta-analysis

The relevant study results were combined using a three-level hierarchical Bayesian NMA, as previously described in Ferguson et al. [20]. For convenience, the methods are summarized here. The methods followed the recommended best practice of the NICE Decision Support Unit for evidence synthesis [22, 23]. The NMA was conducted using WinBUGS (a Markov chain Monte Carlo simulation-based software for Bayesian inference) version 1.4.3. The code was based on that recommended by the NICE Decision Support Unit [24]. The relevant study results were combined using a three-level hierarchical Bayesian NMA model that accounted for the exchangeability between treatments within the same class [2527]. Individual treatments were classified under different classes as: LAMA monotherapy, ICS + LABA therapy, triple therapy (ICS/LAMA/LABA) and LAMA + LABA (reference treatment). The base case NMA included only double-blind studies.

Underlying treatment effects within each class were assumed to follow a normal distribution with class-specific mean and variance to account for the exchangeability of treatment effects within the same class. An additional scenario analysis was conducted using an independent treatment effect model, wherein the treatment effect is drawn from a treatment-specific underlying distribution.

Results were generated using both random- and fixed-effects models and were compared for goodness of fit to the data, calculated as the overall mean residual deviance. Goodness of fit was assessed using the deviance information criterion (DIC); the model with the lowest DIC was considered the model with the best fit to the data.

One of the prerequisites for conducting an NMA is the assumption of consistency between direct and indirect evidence. Inconsistencies between direct and indirect estimates were checked for all outcomes whose networks included closed loops.

A separate NMA was performed for each of the following outcomes: rate of moderate-to-severe exacerbations, rate of severe exacerbations, change from baseline in trough forced expiratory volume in 1 second (FEV1) at 24 and 52 weeks, change from baseline in St George’s Respiratory Questionnaire (SGRQ) total score at 24 and 52 weeks, proportion of SGRQ responders (patients who experienced an improvement in SGRQ total score that met or exceeded the minimum clinically important difference of ≥ 4 units) at 24 and 52 weeks, Transition Dyspnea Index (TDI) focal score at 24 and 52 weeks, change from baseline in daily rescue medication use over 52 weeks, adverse events (AEs) (any AEs, serious AEs, upper respiratory tract infections [URTIs] and cases of pneumonia over 52 weeks) and withdrawals (all-cause and due to AE) over 52 weeks.

The NMA model estimated mean differences (MDs) for FEV1, SGRQ, TDI and rescue medication change from baseline, rate ratios (RRs) for exacerbation outcomes and odds ratios (ORs) for SGRQ responders (defined as improvement in SGRQ score ≥ 4 units) and safety/tolerability outcomes. For pneumonia, the NMA was conducted using a risk difference (RD) model in the base case rather than the odds ratio due to the low event rates observed. The number needed to benefit (NNTB; number needed to treat for 1 year to prevent one moderate/severe exacerbation) and the number needed to harm (NNTH; number needed to treat for 1 year for there to be one extra patient with pneumonia) were calculated using the absolute RD between the event or incidence rates in the control group (LAMA/LABA) and the active treatment group (ICS/LAMA/LABA).

For triple combinations where more than one dose level has been studied, results are presented for the dose(s) currently approved and licensed (as a triple FDC or as dual therapy plus monotherapy that can be prescribed as open triple therapy). Studies reporting data at 20–28 weeks were included in the 24-week analyses and those reporting data at 48–56 weeks were included in the 52-week analyses. For the exacerbation rates, all studies > 10 weeks were included.

Meta-regression and sensitivity analyses account for heterogeneity across studies. A sensitivity analysis was undertaken by adding open-label studies to the base case network of double-blind studies. Sensitivity analyses were also conducted using subgroups according to the following factors: symptomatic population (excluding studies with no requirement for patients to be symptomatic), exacerbation history (excluding studies not requiring prior exacerbation history) and trial duration (excluding studies < 24 weeks). A univariate meta-regression analysis (using age, gender, body mass index (BMI), smoking status, COPD severity and exacerbation history) was performed for exacerbation outcomes.

Compliance with Ethics Guidelines

This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.

Results

Study Selection

The systematic literature review process is shown in Fig. 1. Initial database searches identified 16,518 publications, with 2755 removed because of duplication across databases searched. Initial screening reduced eligible publications to 1616, which were subject to full-text review. A further 33 citations were identified from the conference proceedings and bibliographies of identified publications, together with two clinical study reports for BUD/GLY/FOR RCTs. A total of 19 studies from 178 publications met the inclusion criteria of the review. Of these, two studies by Siler et al. [28] met the inclusion criteria; however, they could not be connected in the base-case network, omitting them from the NMA. Additionally, two studies were excluded from the base case (but included in sensitivity analyses) as they were open label [2, 4], leaving a total of 15 double-blind studies that contributed to the base-case network.

Fig. 1.

Fig. 1

PRISMA flowchart of study screening process. CSR clinical study report

Study Characteristics

All 19 studies identified in the systematic literature review were multicenter, the majority were phase III, two were open label, and the remainder were double blind; the majority were 24 or 52 weeks in duration (Table 2; Table S2).

Table 2.

Study characteristics

Study Treatment Patient number Study duration (weeks) Primary endpoint Publication type Study phase Blinding Study setting

Aaron 2007 [41]

ISRCTN29870041

FP/SAL (FP 500 µg + SAL 50 µg) BID + TIO 18 µg OD 145 52 Proportion of patients who experienced a COPD exacerbation that required treatment with systemic steroids or antibiotics within 52 weeks of randomization Journal article Unclear Double-blind Multicenter
TIO 18 µg OD + SAL 50 µg BID 148
TIO 18 µg OD 156

Bremner 2018a [42]

NCT02729051

FF/UMEC/VIL (FF 100 µg

 + UMEC 62.5 µg + VIL 25 µg) OD

527 24 Change from baseline in trough FEV1 at Week 24 Journal article III Double-blind Multicenter
FF/VIL (FF 100 µg + VIL 25 µg) OD + UMEC 62.5 µg OD 528

ETHOS [19]

NCT02465567

BUD/GLY/FOR (BUD 320 µg

 + GLY 18 µg + FOR 9.6 µg) BID

2137 52 Annual rate of moderate-to-severe COPD exacerbations Journal article III Double-blind Multicenter

BUD/GLY/FOR (BUD 160 µg

 + GLY 18 µg + FOR 9.6 µg) BID

2121
GLY/FOR (GLY 18 µg + FOR 9.6 µg) BID 2120
BUD/FOR MDI (BUD 320 µg + FOR 9.6 µg) BID 2131

FULFILa [43]

NCT02345161

FF/UMEC/VIL (FF 100 µg + UMEC 62.5 µg + VIL 25 µg) OD 911 24 Change from baseline in trough FEV1 at Week 24, change from baseline in SGRQ total score at Week 24 Journal article/CSR III Double-blind Multicenter international

BUD/FOR DPI (BUD 320 µg

 + FOR 9 µg) BID

899

Hanania 2012a [44]

NCT00784550

FP/SAL (FP 250 µg + SAL 50 µg) BID + TIO 18 µg OD 173 24 Change from baseline in morning pre-dose FEV1 at Week 24 Journal article IV Double-blind Multicenter
TIO 18 µg OD 169

IMPACTa [6]

NCT02164513

FF/UMEC/VIL (FF 100 µg

 + UMEC 62.5 µg + VIL 25 µg) OD

4155 52 Annual rate of moderate or severe COPD exacerbations over 52 weeks Journal article/CSR III Double-blind Multicenter international
FF/VIL (FF 100 µg + VIL 25 µg) OD 4139

UMEC/VIL (UMEC 62.5 µg

 + VIL 25 µg) OD

2073

KRONOSa [18]

NCT02497001

BUD/GLY/FOR (BUD 320 µg

 + GLY 18 µg + FOR 9.6 µg) BID

640 24

Japan/China

Change from baseline in morning pre-dose trough FEV1 over Weeks 12–24

EU/Canada

Change from baseline in morning pre-dose trough FEV1 over 24 weeks, FEV1 AUC0–4 h over 24 weeks

USA

FEV1 AUC0–4 at Week 24, change from baseline in morning pre-dose trough FEV1 at Week 24

Journal article/CSR III Double-blind Multicenter international
GLY/FOR (GLY 18 µg + FOR 9.6 µg) BID 627

BUD/FOR MDI (BUD 320 µg

 + FOR 9.6 µg) BID

316

BUD/FOR DPI (BUD 320 µg

 + FOR 9 µg) BID

319

Study 200109a [3]

NCT01957163

FF/VIL (FF 100 µg + VIL 25 µg) OD + UMEC 125 µg OD 207 12 Change from baseline in trough FEV1 at Day 85 (Week 12) Journal article III Double-blind Multicenter international
FF/VIL (FF 100 µg + VIL 25 µg) OD + UMEC 62.5 µg OD 206
FF/VIL (FF 100 µg + VIL 25 µg) OD 206

Study 200110a [3]

NCT02119286

FF/VIL (FF 100 µg + VIL 25 µg) OD + UMEC 125 µg OD 207 12 Change from baseline in trough FEV1 at Day 85 (Week 12) Journal article III Double-blind Multicenter international
FF/VIL (FF 100 µg + VIL 25 µg) OD + UMEC 62.5 µg OD 206
FF/VIL (FF 100 µg + VIL 25 µg) OD 206

SUNSETa [45]

NCT02603393

FP/SAL (FP 500 µg + SAL 50 µg) BID + TIO 18 µg OD 526 26 Change from baseline in post-dose trough FEV1 at Week 26 Journal article IV Double-blind Multicenter international
GLY/IND (GLY 54 µg + IND 85 µg) OD 527

TRIBUTEa [8]

NCT02579850

BDP/GLY/FOR (BDP 174 µg

 + GLY 18 µg + FOR 10 µg) BID

764 52 Annual rate of moderate-to-severe COPD exacerbations over 52 weeks Journal article III Double-blind Multicenter international
GLY/IND (GLY 54 µg + IND 85 µg) OD 768

TRILOGYa [5]

NCT01917331

BDP/GLY/FOR (BDP 200 µg

 + GLY 25 µg + FOR 12 µg) BID

687 52 Change from baseline in pre-dose (morning) FEV1, change from baseline in 2 h post-dose FEV1, and TDI focal score at Week 26 Journal article III Double-blind Multicenter international
BDP/FOR (BDP 200 µg + FOR 12 µg) BID 681

TRINITYa [46]

NCT01911364

BDP/GLY/FOR (BDP 200 µg

 + GLY 25 µg + FOR 12 µg) BID

1078 52 Moderate-to-severe COPD exacerbation rate for 52 weeks of treatment Journal article III Double-blind Multicenter international
BDP/FOR (BDP 200 µg + FOR 12 µg) BID + TIO 18 µg OD 538
TIO 18 µg OD 1075

Welte 2009 [47]

NCT00496470

BUD/FOR DPI (BUD 320 µg

 + FOR 9 µg) BID + TIO 18 µg OD

329 12 Change in pre-dose FEV1 from randomization (Week 0) to the full treatment period (mean FEV1 at Weeks 1, 6, and 12 of treatment) Journal article IV Double-blind Multicenter international
TIO 18 µg OD 331

WISDOM [48]

NCT00975195

FP 500 µg BID + SAL 50 µg BID + TIO 18 µg OD 1244 52 Time to the first moderate-to-severe COPD exacerbation Journal article IV Double-blind Multicenter international
FP 500 µg BID (reducingb) + SAL 50 µg BID + TIO 18 µg OD 1244
Not included in the base case network
Jung 2012 [2] FP/SAL (FP 250 µg + SAL 50 µg) BID + TIO 18 µg OD 237 24 Change from baseline in pre-bronchodilator FEV1 at Week 24 Journal article IV Open- label Multicenter
TIO 18 µg OD 242

Lee 2016 [4]

NCT01397890

BUD/FOR DPI (BUD 320 µg

 + FOR 9 µg) BID + TIO 18 µg OD

287 12 Change from baseline in pre-bronchodilator FEV1 at Weeks 1, 6, and 12 Journal article IV Open- label Multicenter international
TIO 18 µg OD 291

Study AC4116135a [28]

NCT01772134

FP/SAL (FP 250 µg + SAL 50 µg) BID + UMEC 125 µg OD 205 12 Change from baseline in trough FEV1 at Day 85 (Week 12) Journal article III Double-blind Multicenter international
FP/SAL (FP 250 µg + SAL 50 µg) BID + UMEC 62.5 µg OD 204
FP/SAL (FP 250 µg + SAL 50 µg) BID 205

Study AC4116136a [28]

NCT01772147

FP/SAL (FP 250 µg + SAL 50 µg) BID + UMEC 125 µg OD 202 12 Change from baseline in trough FEV1 at Day 85 (Week 12) Journal article III Double-blind Multicenter international
FP/SAL (FP 250 µg + SAL 50 µg) BID + UMEC 62.5 µg OD 203
FP/SAL (FP 250 µg + SAL 50 µg) BID 201

Doses represent the total amount per administered dose, which may be the sum of two actuations. Fixed-dose combinations are represented with ‘/’ between components; open combinations are represented with ‘+’ between components

AUC0–4 area under the curve from 0 to 4 h, BDP beclomethasone dipropionate; BID twice daily; BUD budesonide, CAT COPD assessment test; COPD chronic obstructive pulmonary disease, CSR clinical study report, DPI dry powder inhaler, FEV1 forced expiratory volume in 1 s, FF fluticasone furoate, FP fluticasone propionate, FOR formoterol, GLY glycopyrronium bromide, IND indacaterol, MDI metered dose inhaler, mMRC modified Medical Research Council dyspnea scale, OD once daily, SAL salmeterol, SGRQ St. George’s Respiratory Questionnaire, TDI Transition Dyspnea Index, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

aA majority of the patient population was classified as symptomatic at baseline (based on CAT ≥ 10 or mMRC ≥ 2)

bThe BID dose of FP was reduced every 6 weeks in a stepwise withdrawal, from 500 to 250 μg, then to 100 μg, and finally to 0 μg (placebo) [48]

The majority of studies included in the NMA were adjudged to pose a low risk of bias with respect to randomization, baseline characteristics, balance of withdrawals between groups and statistical methodology (Table S3). The two open-label studies, which were excluded from the base case, were associated with a high risk of performance and detection bias [2, 4].

Analysis Assumptions

Comparison of triple therapies using all treatments as reported was not possible because of the absence of a common comparator between treatments of interest, which prevented the formation of an interlinking network (Fig. 2a). To resolve the disconnected network, LAMA/LABA combinations were grouped into a single treatment node on the assumption that each has a comparable efficacy in moderate-to-severe COPD, as supported by multiple, previously published meta-analyses [2932], allowing an interlinked network to be created (Fig. 2b).

Fig. 2.

Fig. 2

Networks using treatments as reported (a) and using all LAMA/LABA treatments as a single treatment group (b). BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, DPI dry powder inhaler, F fixed-dose combination triple therapy, FF fluticasone furoate, FOR formoterol, FP fluticasone propionate, GLY glycopyrronium bromide, IND indacaterol, LABA long-acting β2-agonist, LAMA long-acting muscarinic antagonist, MDI metered dose inhaler, O open triple therapy, OD once daily, red reducing dose of fluticasone, SAL salmeterol, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

Patient Baseline Clinical Characteristics

A total of 37,741 evaluable patients contributed to the NMA. Average patient characteristics of the included double-blind studies were similar in terms of age, gender, BMI, smoking status and disease duration, but differences were noted in race (likely as a result of different regional recruitment), symptom burden, COPD severity and exacerbation history. The patient characteristics of two open-label studies differed from double-blind studies in terms of gender, disease duration, race and BMI parameters (Table 3).

Table 3.

Patient baseline clinical characteristics

Study Mean age (years) Male (%) Race (%; white) Disease duration (years) Current smoker (%) BMI (kg/m2) COPD severity (%; GOLD 1/2/3/4) Moderate-to-severe exacerbation history, ≥ 1 exacerbations (%) Mean CAT score Mean mMRC score
Aaron 2007 [41] 68 56 98 NR 28 28 NR 100 NR NR
Bremner 2018a [42] 66 75 NR NR 38 NR < 1/35/49/15 100 19.9 NR
FULFILa [43] 64 74 85 NR 44 27 < 1/33/54/13 65 19.1 NR
ETHOS [19] 65 60 85 8 41 27 NA/29/61/11 100 19.6 NR
Hanania 2012a [44] 61 47 96 7 58 27 NA/68/32/NA 29b NR 2.5
IMPACTa [6] 65 66 78 NR 35 27 < 1/36/48/16 100 20.1 NR
KRONOSa [18] 65 71 50 7 40 26 < 1/49/43/8 26 18.3 NR
Study 200109a [3] 64 66 98 NR 42 28 NA/40/46/14 15b 16.6 2.5
Study 200110a [3] 63 63 86 NR 57 27 NA/48/41/11 14b 17.6 2.3
SUNSETa [45] 65 71 100 8 42 28 NA/70/30/NA 34 NR NR
TRIBUTEa [8] 64 72 92 8 45 26 NA/NA/79/20 100 21.2c NR
TRILOGYa [5] 64 76 100 8 47 26 NA/NA/77/23 100 20.8 NR
TRINITYa [46] 63 76 99 8 48 26 NA/NA/79/21 100 21.6 NR
Welte 2009 [47] 62 75 NR 6d 44 26 NA/25/64/11 100 NR NR
WISDOM [48] 64 82 81 8 33 25 < 1/< 1/61/38 100 NR 1.8
Not included in the base-case network
Jung 2012 [2] 67 98 NR NR NR 22 NA/58/38/3 NR NR NR
Lee 2016 [4] 67 96 NR 5 NR 21 NA/8/74/18 100 NR NR
Study AC4116135a [28] 63 66 88 NR 54 28 NA/46/44/11 21b 18.2 2.4
Study AC4116136a [28] 65 63 82 NR 38 27 NA/40/48/12 31b 17.7 2.4

Baseline characteristics were obtained from publicly available clinical study reports when not available in the primary publication

BMI body mass index, CAT COPD assessment test; COPD chronic obstructive pulmonary disease, GOLD Global Initiative for Obstructive Lung Disease, mMRC Modified Medical Research Council, NA not applicable, NR not reported

aA majority of the patient population was classified as symptomatic at baseline (based on CAT ≥ 10 or mMRC ≥ 2)

bModerate exacerbation history (moderate-to-severe not reported)

cReported in [49]

dMedian (mean not reported)

Adjustment for differences in important treatment effect modifiers using meta-regression was carried out for exacerbation endpoints, as the number of studies contributing to each NMA was limited for other outcomes. Twelve of the 17 included studies enrolled only symptomatic patients, and for 10 of the 17 included studies, all enrolled patients had a history of moderate-to-severe exacerbations in the previous year. Subgroup analyses were carried out in both of these subsets.

Efficacy

For each outcome, the findings are presented for all comparisons with data available within the network. The primary objective was to compare BUD/GLY/FOR to other triple combination therapies, but the results for BUD/GLY/FOR versus dual therapies are also provided in the supplementary information.

Exacerbation Rates

Moderate-to-severe and severe exacerbations were reported in 14 and 13 studies, respectively (networks shown in Fig. S1). BUD/GLY/FOR 320/18/9.6 μg showed comparable reductions to two other triple ICS/LAMA/LABA fixed-dose combinations—(beclomethasone dipropionate/glycopyrronium bromide/formoterol fumarate [BDP/GLY/FOR 200/25/12 μg twice daily (BID)] and fluticasone furoate/umeclidinium/vilanterol [FF/UMEC/VIL 100/62.5/25 µg once daily (OD)])—and six open triple combinations for both moderate-to-severe and severe exacerbations (Fig. 3A and B). BUD/GLY/FOR 320/18/9.6 μg significantly reduced moderate-to-severe exacerbation rates versus all dual combination therapies in the network and severe exacerbation rates versus LAMA/LABA (Table S4).

Fig. 3.

Fig. 3

Rate ratio of moderate-to-severe (a) and severe (b) exacerbations. Data from REM. BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, CrI credible interval, DPI dry powder inhaler, F fixed-dose combination triple therapy, FF fluticasone furoate, FOR formoterol, FP fluticasone propionate, GLY glycopyrronium bromide, O open triple therapy, OD once daily, red reducing dose of fluticasone, REM random effects model, RR rate ratio, SAL salmeterol, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

Lung Function

Changes from baseline in trough FEV1 at 52 weeks were reported in eight studies, respectively (networks shown in Fig. S2). At 52 weeks, BUD/GLY/FOR 320/18/9.6 μg showed comparable improvement in trough FEV1 to FF/UMEC/VIL, BDP/GLY/FOR and three open triple combinations (Fig. 4).

Fig. 4.

Fig. 4

Change from baseline in trough FEV1 at 52 weeks. BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, CrI credible interval, F fixed-dose combination triple therapy, FEV1 forced expiratory volume in 1 s, FF fluticasone furoate, FOR formoterol, FP fluticasone propionate, GLY glycopyrronium bromide, MD mean difference, O open triple therapy, OD once daily, red reducing dose of fluticasone, SAL salmeterol, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

Similar results were observed for trough FEV1 at 24 weeks (Figs. S3 and S4). Lung function outcomes for BUD/GLY/FOR 320/18/9.6 μg versus dual combination therapies at 24 and 52 weeks are shown in Table S4. BUD/GLY/FOR 320/18/9.6 μg showed significant improvements in trough FEV1 versus all dual therapy comparators at both 24 and 52 weeks (Table S4).

Quality of Life and Symptoms

Changes from baseline in total SGRQ score at 52 weeks were reported in eight studies (networks shown in Fig. S5). At 52 weeks, BUD/GLY/FOR 320/18/9.6 μg showed comparable improvement in the total SGRQ score to FF/UMEC/VIL, BDP/GLY/FOR and three open triple combinations (Fig. 5a).

Fig. 5.

Fig. 5

HRQoL and symptom endpoints. Change from baseline in SGRQ total score (a), SGRQ responders (b) and TDI focal score (c) at 52 weeks; change from baseline in daily rescue medication use over 52 weeks (d). BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, CrI credible interval, F fixed-dose combination triple therapy, FF fluticasone furoate, FOR formoterol, FP fluticasone propionate, GLY glycopyrronium bromide, HRQoL health-related quality of life, MD mean difference, O open triple therapy, OD once daily, OR odds ratio, red reducing dose of fluticasone, SAL salmeterol, SGRQ St George’s Respiratory Questionnaire, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

SGRQ responders at Week 52 were reported in six studies. At 52 weeks, BUD/GLY/FOR 320/18/9.6 μg showed a comparable SGRQ responder rate to FF/UMEC/VIL, BDP/GLY/FOR and the open triple therapy comprising tiotropium + beclomethasone dipropionate + formoterol fumarate (BDP/FOR 200/12 μg BID + TIO 18 μg OD; Fig. 5b).

Changes at Week 52 in TDI focal score were reported in four studies. At 52 weeks, BUD/GLY/FOR 320/18/9.6 μg showed comparable improvements in TDI focal score to FF/UMEC/VIL and an open triple combination fluticasone propionate (FP)/salmeterol (SAL) 500/50 μg BID + TIO 18 μg OD (Fig. 5c).

Rescue medication use over 52 weeks was reported in six studies. Over 52 weeks, BUD/GLY/FOR showed comparable reduction in mean puffs per day of rescue medication to FF/UMEC/VIL, BDP/GLY/FOR and the open triple combination BDP/FOR 200/12 μg BID + TIO 18 μg OD (Fig. 5d).

The results for quality of life and symptom outcomes at 24 weeks were similar to the 52-week findings (Figs. S6 and S7). Quality of life and symptom outcomes for BUD/GLY/FOR 320/18/9.6 μg versus dual combination therapies at 24 and 52 weeks are shown in Table S4. BUD/GLY/FOR 320/18/9.6 μg showed significant improvements in SGRQ outcomes and comparable or greater improvements in TDI score and rescue medication versus all dual therapy comparators (Table S4).

Safety and Tolerability

Networks for safety outcomes are shown in Fig. S8. A total of eight studies presented results for any AE, serious AE and pneumonia (any grade) outcomes, respectively, over 52 weeks. A total of three studies presented results for URTIs over 52 weeks (networks shown in Fig. S8). A comparable safety profile in terms of any AEs, serious AEs, pneumonia and URTIs was observed among BUD/GLY/FOR, FF/UMEC/VIL, BDP/GLY/FOR and all triple combinations, with data available within the network for each of these outcomes (Fig. 6a–d).

Fig. 6.

Fig. 6

Safety endpoints. AEs (a), SAEs (b), pneumonia (any grade) (c) and URTI (any grade) (d) at 52 weeks. AEs adverse events, BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, CrI credible interval, F fixed-dose combination triple therapy, FF fluticasone furoate, FOR formoterol, FP fluticasone propionate, GLY glycopyrronium bromide, O open triple therapy, OD once daily, OR odds ratio, RD risk difference, red reducing dose of fluticasone, SAEs serious adverse events SAL salmeterol, TIO tiotropium, UMEC umeclidinium, URTI upper respiratory tract infection, VIL vilanterol trifenatate

A total of eight studies presented results for all withdrawals and withdrawals due to AEs, respectively, at 52 weeks (networks shown in Fig. S9). BUD/GLY/FOR 320/18/9.6 μg showed a comparable tolerability profile to FF/UMEC/VIL, BDP/GLY/FOR and open triple combinations in terms of all-cause withdrawals and withdrawals due to AEs (Fig. 7).

Fig. 7.

Fig. 7

Tolerability endpoints. All withdrawals (a) and withdrawals due to an AE (b) at 52 weeks. AE adverse event, BDP beclomethasone dipropionate, BID twice daily, BUD budesonide, F fixed-dose combination triple therapy, FF fluticasone furoate, FP fluticasone propionate, FOR formoterol, GLY glycopyrronium bromide, O open triple therapy, OD once daily, OR odds ratio, red reducing dose of fluticasone, SAL salmeterol, TIO tiotropium, UMEC umeclidinium, VIL vilanterol trifenatate

Comparisons of BUD/GLY/FOR 320/18/9.6 μg to dual therapies for safety and tolerability outcomes are shown in Table S4. BUD/GLY/FOR 320/18/9.6 μg showed a comparable safety profile to all dual therapy comparators, with the exception of a slightly higher risk of pneumonia and a lower risk of withdrawals and AE withdrawals versus LAMA/LABA (Table S4).

Statistical Heterogeneity and Inconsistency

For the majority of outcomes at 52 weeks, no inconsistency was observed; statistical heterogeneity assessments were not possible because of the limited number of studies. For moderate-to-severe and severe exacerbations, the results of the consistency assessment showed inconsistency and heterogeneity (I2: 0–92% for moderate-to-severe exacerbations and 0–83% for severe exacerbations). A sensitivity analysis was conducted by excluding studies not requiring prior exacerbation history from the base-case network, which removed the inconsistency and heterogeneity and produced comparable conclusions (Tables S5 and S6).

Sensitivity Analyses and Meta-regression

The results of sensitivity analyses were in line with the base-case results for all outcomes (Tables S5–S7). Analyses of lung function and symptom outcomes, including open-label studies, produced results in line with the base-case model, which only included double-blind studies. For exacerbation outcomes, sensitivity analyses and meta-regression findings (including the analysis of exacerbations excluding studies < 24 weeks) were aligned with the base-case model (Tables S5 and S8, respectively). In addition to the base-case class effect models, all outcomes were also analyzed using independent treatment effect models, and the results were generally in line with the base-case analyses for all triple comparisons (Tables S9 and S10).

Discussion

The primary analysis of this systematic literature review and NMA compared the efficacy, safety and tolerability of BUD/GLY/FOR with other triple ICS/LAMA/LABA open or fixed-dose combinations in the treatment of moderate-to-very-severe COPD. Secondary analyses compared BUD/GLY/FOR with dual therapies. NMAs provide important evidence for developing healthcare guidelines and are useful where direct head-to-head trials are lacking [33, 34]; to date, there are no head-to-head trials of triple FDCs. In evaluating the current evidence regarding triple therapies in COPD, this NMA provides important context for healthcare providers and payers.

The findings of this NMA suggested that the efficacy of BUD/GLY/FOR was comparable to all other fixed-dose (FF/UMEC/VIL and BDP/GLY/FOR) and open triple ICS/LAMA/LABA combination therapies with respect to reducing exacerbation rates and rescue medication use and improving lung function, quality of life and symptoms at/over 52 weeks. The addition of the ETHOS study results (n = 8509) continued to support the previous findings of Ferguson and colleagues, who found that all fixed-dose and open combinations showed comparable efficacy in reducing exacerbation rates, and improving lung function and symptoms in patients with moderate-to-very-severe COPD at/over 24 weeks [20]. In addition, this was the first NMA to assess tolerability outcomes associated with different triple therapy FDCs. It was shown that BUD/GLY/FOR 320/18/9.6 μg had comparable safety and tolerability profiles to FF/UMEC/VIL and BDP/GLY/FOR, in addition to several available open triple combinations.

Given the similarity of the triple combinations in our NMA, we subsequently calculated the NNTB and NNTH for the triple combinations compared with LAMA/LABA for exacerbation and pneumonia outcomes, as this is a key area of interest for ICS-containing therapies in COPD (Table S11). All fixed-dose and open triple combinations were more effective than LAMA/LABA in reducing moderate-to-severe exacerbations, each with an NNTB of 3–4 (Table S11). BUD/GLY/FOR and FF/UMEC/VIL FDCs were more effective than LAMA/LABA in reducing severe exacerbations, each indicating a NNTB of 3 (Table S11). All fixed-dose and open triple combinations were associated with higher risk of pneumonia compared with LAMA/LABA, with a comparable NNTH of 61–75 for one extra patient with pneumonia (Table S11). However, these NNT analyses should be interpreted with caution as these were a function of baseline risk, which could vary across trials. It should be noted that when there is no statistically significant difference between treatment groups, the credibility interval contains the potential for both benefit and harm.

The comparability of BUD/GLY/FOR with other fixed-dose and open triple combinations in clinical well-controlled, randomized study settings raises the importance of other factors, such as inhaler device, patient preferences and therapeutic education [1]. While we did not observe any meaningful differences between fixed and open triple combinations in the NMA, a retrospective observational study of patients with COPD who were receiving LAMA, LABA and/or ICS therapy in either single or multiple inhalers showed higher adherence to therapy when delivered via a single inhaler compared with therapy delivered via multiple inhalers [35]. This evidence suggests that triple therapy FDCs may result in better patient outcomes compared with open triple combinations in real-world use. Poor inhaler technique has also been associated with poor disease outcomes in COPD [36], and therefore it is important to ensure that patients are prescribed appropriate inhalers that take into account their preferences, disease characteristics and handling abilities. In a patient survey study, patients forced to switch from a metered dose inhaler (MDI) to a dry powder inhaler (DPI) therapy for non-therapeutic reasons, due to formulary changes, reported substantial morbidity, suggesting that unfamiliarity with a new device may have a negative impact on symptoms and quality of life [37]. Overall, both patient education and familiarity with a device continue to be important aspects in maintaining treatment adherence and positive clinical outcomes in a real-world setting.

An NMA allows many treatments to be connected without the requirement of head-to-head comparisons between treatments required by pairwise analyses [38]; however, several limitations of the NMA methodology should be acknowledged. Different LAMA/LABA combinations were grouped under a single treatment class to resolve the disconnected network. While this approach has been used in previous meta-analyses [4, 5], and differentiating between distinct LAMA/LABAs was not an objective of this NMA, it means that intra-class differences among LAMA/LABA would not have been captured within the analyses. However, numerous previous NMAs have shown no significant differences among the LAMA/LABA class [2932, 39], particularly with respect to exacerbations or symptom outcomes, suggesting that the assumption of similar efficacy is reasonable. While the studies included in this NMA were broadly similar, there were some differences in study design and patient populations across studies, including symptom requirements and exacerbation history. Potential sources of clinical heterogeneity were explored in sensitivity analyses and meta-regression where possible. Sensitivity analyses excluding studies that did not require a specific symptom burden or previous exacerbation history from the base-case network were in line with the overall findings for exacerbation outcomes. In addition to the base-case class effect models, all outcomes were also analyzed using independent treatment effect models and the results were generally in line with the base-case analyses for all triple comparisons. The study populations were similar across studies (moderate-to-very-severe COPD), and the studies included in the NMA were generally considered to have a low risk of bias. Finally, more data are needed to evaluate the relative efficacy of triple combinations in reducing mortality as the currently available network is sparse and the incidence of fatal events is low in most COPD studies. There are also differences in death reporting across studies; for example, some report mortality as time to event endpoint, while others report data for the proportion of patients who died, making comparison difficult and requiring strong assumptions to perform a network meta-analysis.

Conclusion

In conclusion, this NMA showed BUD/GLY/FOR 320/18/9.6 μg to have comparable efficacy to other ICS/LAMA/LABA open and FDC therapies in terms of reducing exacerbation rates and improving lung function, symptoms and health-related quality of life when studied in RCTs of patients with moderate-to-very-severe COPD. In addition, this NMA was the first to assess safety and tolerability outcomes associated with different triple therapy FDCs and showed BUD/GLY/FOR 320/18/9.6 μg to have a comparable safety and tolerability profile to other ICS/LAMA/LABA open and FDC therapies. Consistent with head-to-head trial data, BUD/GLY/FOR 320/18/9.6 μg showed a significantly better efficacy profile versus dual combinations. The findings of this NMA are aligned with the findings of previously published meta-analysis results of triple combinations in COPD.

Supplementary Information

Below is the link to the electronic supplementary material.

Acknowledgements

We thank Akanksha Sharma of Parexel International for her valuable contributions to the study.

Funding

This study was supported by AstraZeneca. The sponsor funded the journal’s Rapid Service and Open Access fees.

Medical Writing and Editorial Assistance

Medical writing support, under the direction of the authors, was provided by Jake Casson, PhD, of CMC Connect, McCann Health Medical Communications, funded by AstraZeneca in accordance with Good Publication Practice (GPP3) guidelines [40].

Authorship

All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this article, take responsibility for the integrity of the work as a whole, and have given their approval for this version to be published.

Author Contributions

Ulf Holmgren, Mario Ouwens, Martin Jenkins, and Enrico De Nigris made substantial contributions to the conception and design of the study. Barinder Singh and Mohd Kashif Siddiqui performed the meta-analysis. All authors contributed to the interpretation of the data, critically revised the manuscript, approved the final version to be submitted, and agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Disclosures

Arnaud Bourdin reports grants, personal fees, non-financial support, and other from AstraZeneca; grants, personal fees, non-financial support, and other from Boehringer Ingelheim; grants, personal fees, non-financial support, and other from GlaxoSmithKline; personal fees, non-financial support, and other from Novartis; personal fees and non-financial support from Teva; personal fees, non-financial support, and other from Regeneron; personal fees, non-financial support, and other from Chiesi Farmaceutici; grants, personal fees, non-financial support, and other from Actelion; personal fees from Gilead; non-financial support and other from Roche; other from Nuvaira, from null, outside of the submitted work. Nicolas Molinari reports grants and personal fees from AstraZeneca outside the submitted work. Gary T. Ferguson reports grants, personal fees, and non-financial support from AstraZeneca during the conduct of the study; grants, personal fees, and non-financial support from AstraZeneca, Boehringer Ingelheim, Novartis, Pearl – a member of the AstraZeneca Group, and Sunovion; grants and personal fees from Theravance; personal fees from Circassia, GlaxoSmithKline, Innoviva, Mylan, and Verona, outside of the submitted work. Ulf Holmgren, Mario Ouwens, Martin Jenkins and Enrico De Nigris are employees of AstraZeneca and hold stock and/or stock options in the company. Mohd Kashif Siddiqui is an employee of Parexel International. Barinder Singh is a former employee of Parexel International.

Compliance with Ethics Guidelines

This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.

Data Availability

The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Data Availability Statement

The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.


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