Idiopathic pulmonary fibrosis: lessons from clinical trials over the past 25 years

Lesson learned: this triple combination should not be used in patients with IPF

The first randomised double-blind trial undertaken in IPF was of prednisone plus placebo versus prednisone plus azathioprine. This trial suggested a potential therapeutic benefit from prednisone plus azathioprine on lung function and survival [13]. In a separate pilot study, the addition of N-acetylcysteine (NAC), a precursor of the antioxidant glutathione, to prednisone and azathioprine improved pulmonary function tests in patients with “fibrosing alveolitis” (a term used in the 1980s–1990s likely to refer to what we currently recognise as idiopathic interstitial pneumonia) [35]. Triple therapy with prednisone, azathioprine and NAC became widely used as a treatment for IPF based on its potential to counteract the oxidative stress thought to contribute to progression of the disease. In the IFIGENIA trial, 155 randomised patients received high-dose NAC (600 mg, three times a day) or placebo, with patients in both groups receiving prednisone and azathioprine [14]. The results were promising, as patients in the triple-therapy group showed a reduced deterioration in vital capacity (VC) and diffusing capacity of the lung for carbon monoxide (D_LCO) over 1 year. However, interpretation of the results was limited by the high patient drop-out rate (approximately 30% in each treatment group) and the lack of a true placebo arm.

To establish the efficacy and safety of triple therapy (NAC, prednisone and azathioprine) and NAC monotherapy, the randomised placebo-controlled PANTHER-IPF trial was conducted in 236 patients with IPF [15]. The primary endpoint was changed from baseline in FVC at week 60 but the triple-therapy arm was stopped after 32 weeks when an interim analysis showed significantly higher rates of death and hospitalisation in patients treated with triple therapy compared to placebo. The NAC monotherapy and placebo arms continued and, at the end of the trial, the results showed no overall difference between the NAC monotherapy and placebo groups in terms of change from baseline in FVC or any differences in mortality [16]. These findings resulted in a strong recommendation against the use of this triple-therapy regimen and a conditional recommendation against the use of NAC monotherapy in the most recent clinical practice guidelines for the treatment of IPF [36]. However, in a subgroup analysis, NAC was associated with a significant reduction in the risk of a composite endpoint when assessing disease progression in patients with a TT-genotype of the host defence gene TOLLIP but a trend towards increased risk in patients with a CC-genotype [37]. While acknowledging that these promising data come from a subgroup of patients, genotype-stratified prospective, randomised trials are required to investigate further the effects of NAC in patients with IPF [38].

Lesson learned: the need for large placebo-controlled trials with meaningful endpoints

In 1999, results from the first trial of the cytokine interferon gamma-1b in patients with IPF showed that, after 12 months' open-label treatment, all nine patients treated with interferon gamma-1b plus prednisolone had a substantial improvement in total lung capacity, whereas all nine patients treated with prednisolone alone showed deterioration [39]. Interest in this therapeutic approach led to a placebo-controlled trial of interferon gamma-1b in 330 patients with IPF [17]. This showed no benefit of interferon gamma-1b for progression-free survival, lung function or quality of life (table 1). The following INSPIRE trial, which assessed the effect on survival of interferon gamma-1b versus a placebo in 826 patients with IPF, was terminated early when an interim analysis showed no difference between treatment groups [18]. These findings were reflected in the 2011 clinical practice guidelines, which gave a strong recommendation against the use of interferon gamma in patients with IPF [1].

Pre-clinical evidence supporting a role for the coagulation cascade in fibrotic lung diseases led to the hypothesis that anticoagulation therapy might be of benefit in the treatment of IPF [40, 41]. An open-label randomised trial in 56 Japanese patients with IPF who had been admitted to hospital showed that patients treated with prednisolone and an anticoagulant had improved survival rates compared with patients treated with prednisolone alone [42]. However, due to the small size of this study and the absence of an anticoagulant monotherapy or placebo arm, considerable debate remained regarding the risk–benefit ratio of anticoagulation therapy in IPF. The randomised placebo-controlled ACE-IPF trial evaluated the efficacy and safety of warfarin in 145 patients with IPF [19]. This trial was designed to last for 48 weeks but was stopped after a mean follow-up of 28 weeks when an interim analysis showed higher mortality and a low likelihood of benefit with warfarin versus placebo (table 1). This led to a strong recommendation against the use of anticoagulants for the treatment of IPF in the most recent clinical practice guidelines [36]. In addition, a recent post hoc analysis of pooled data from 624 patients with IPF who received a placebo in three clinical trials showed significantly higher mortality at 1 year in patients receiving oral anticoagulants for non-IPF indications, suggesting that the use of anticoagulants in patients with IPF should be based on a careful risk–benefit assessment for the individual patient, coupled with close monitoring during treatment [43].

Lesson learned: effective in pulmonary arterial hypertension but not in idiopathic pulmonary fibrosis

Endothelin-1 is a mediator of epithelial–mesenchymal transition, a fundamental process in the pathogenesis of IPF [44]. The dual endothelin receptor antagonist bosentan, an approved treatment for pulmonary arterial hypertension (PAH), was investigated as a treatment for IPF in two randomised, placebo-controlled, 60-week trials: BUILD-1 and BUILD-3 [20, 21]. In the BUILD-1 trial there was no difference between bosentan and a placebo with respect to the primary endpoint (change from baseline distance in a 6-min walk distance (6-MWD) test at week 60). However, there was a numerical difference in favour of bosentan on time to disease progression or death. The BUILD-3 trial, conducted in patients with an IPF diagnosis of fewer than 3 years' duration (as confirmed by surgical lung biopsy), was designed to evaluate the effect of bosentan in a subpopulation of patients considered more likely to benefit based on the results of BUILD-1. Although bosentan was well tolerated, the BUILD-3 trial showed no difference between bosentan and a placebo with respect to the primary endpoint (worsening of IPF or death) (table 1) [21]. Similarly, although the dual endothelin receptor antagonist macitentan was generally well tolerated, the randomised placebo-controlled MUSIC trial showed no benefit with respect to the primary endpoint (change in FVC over 52 weeks) (table 1) [22]. Thus, the latest clinical practice guidelines for the treatment of IPF include conditional recommendations against the use of bosentan and macitentan [36].

Post hoc subgroup analyses of data from BUILD-1 suggested that patients with little or no honeycombing on high-resolution computed tomography (HRCT) images may have an increased response to bosentan. Based on this observation, the randomised placebo-controlled ARTEMIS-IPF trial was conducted to investigate the efficacy and safety of ambrisentan, a selective endothelin receptor antagonist approved for the treatment of PAH, in patients with IPF and minimal honeycombing. ARTEMIS-IPF was terminated after approximately 34 weeks' exposure when an interim analysis showed that there was a low likelihood of demonstrating efficacy with respect to the primary endpoint (time to disease progression) [23]. Indeed, at the time of the interim analysis a greater proportion of patients treated with ambrisentan rather than a placebo had experienced disease progression, respiratory hospitalisation and death (table 1) [23]. A strong recommendation against the use of ambrisentan was provided in the latest clinical practice guidelines for the treatment of IPF [36].

Lesson learned: not effective in idiopathic pulmonary fibrosis

Tumour necrosis factor-α (TNF-α) is a cytokine that is released by activated alveolar epithelial cells in response to injury and mediates the activation, migration and apoptosis of fibroblasts and myofibroblasts [12]. Etanercept is a recombinant human TNF receptor [45]. Between 2003 and 2005, a randomised, placebo-controlled, 48-week trial was conducted to investigate the efficacy and safety of etanercept in 88 patients with “clinically progressive” IPF [24]. This was the first prospective trial in patients with IPF to include a true placebo group and no differences in lung function endpoints were observed between treatment groups (table 1). This led to a strong recommendation against the use of etanercept in the clinical practice guidelines for the treatment of IPF published in 2011 [1]. No further trials investigating etanercept in patients with IPF have been conducted since this time.

Lesson learned: a trial may fail to meet its primary endpoint but secondary endpoints may indicated patient benefits

Sildenafil is a phosphodiesterase-5 inhibitor that results in pulmonary vasodilation and improvements in gas exchange in patients with IPF [46]. The randomised, placebo-controlled STEP-IPF trial investigated whether sildenafil improved exercise tolerance, dyspnoea and quality of life in 180 patients with IPF and advanced lung function impairment (D_LCO <35% of predicted) [25]. There was no significant difference between the sildenafil and placebo groups with respect to the primary endpoint (proportion of patients with an improvement in 6-MWD of ≥20% at week 12). However, there were significant benefits from sildenafil on the secondary endpoints (arterial oxygenation, D_LCO, dyspnoea and health-related quality of life assessed using the St George's Respiratory Questionnaire (SGRQ)). In a subgroup analysis of patients with right-ventricular systolic dysfunction, those treated with sildenafil had a significantly lower decline in 6-MWD and greater improvement in health-related quality of life than patients treated with a placebo [47]. A conditional recommendation against the use of sildenafil was given in the latest clinical practice guidelines for the treatment of IPF (table 2) [36]; however, sildenafil continues to be investigated as a potential therapy in patients with IPF and severe lung function impairment, for example, in the ongoing randomised INSTAGE trial of sildenafil given in combination with nintedanib versus nintedanib alone (https://clinicaltrials.gov/ct2/show/NCT02802345) and in a randomised study of sildenafil versus placebo added to pirfenidone in patients with advanced IPF and intermediate or high probability of Group 3 pulmonary hypertension (https://clinicaltrials.gov/ct2/show/NCT02951429).

Lesson learned: not effective in idiopathic pulmonary fibrosis

Imatinib is an intracellular inhibitor of multiple tyrosine kinases implicated in fibrogenic pathways in IPF [48–50]. The efficacy and safety of imatinib were investigated in a randomised, placebo-controlled, 96-week trial in patients with IPF and the results showed no benefits for imatinib with respect to the primary endpoint (time to disease progression) (table 1) [26]. The latest clinical practice guidelines include a strong recommendation against the use of imatinib in the treatment of IPF [36].

Lesson learned: not effective in idiopathic pulmonary fibrosis

Simtuzumab is a monoclonal antibody against lysyl oxidase-like 2 (LOXL2), an enzyme secreted by fibroblasts that catalyses cross-linking of extracellular matrix components [51]. A Phase-II, randomised placebo-controlled trial investigating the efficacy and safety of simtuzumab in 544 patients with IPF was terminated prematurely when a preliminary analysis indicated a lack of efficacy on the primary endpoint (progression-free survival) [27]. No further trials investigating agents that act against LOXL2 in patients with IPF have been initiated.

Lesson learned: reduces disease progression in patients with idiopathic pulmonary fibrosis with a manageable safety and tolerability profile

The pyridone derivative pirfenidone exhibits a number of antifibrotic, anti-inflammatory and anti-oxidant effects in vitro and in animal models of lung fibrosis [52–54]; however, it is unclear which of these effects occurs at the doses achieved in humans. Initial observations from a single-arm Phase-II trial suggested potential benefits from pirfenidone in stabilising FVC, total lung capacity and D_LCO in patients with IPF [55]; however, a randomised, placebo-controlled, Phase-II trial conducted with 107 Japanese IPF patients was terminated prematurely after an interim analysis at 6 months showed a higher frequency of acute exacerbations in the placebo group [28]. At the time of the interim analysis there was no significant benefit from pirfenidone on the primary endpoint (change in oxygen saturation during a 6-min steady state exercise test); however, decline in VC was significantly reduced in the pirfenidone group. Three randomised, placebo-controlled, Phase-III trials were initiated to investigate the effect of pirfenidone on lung function: one in Japan and two in North America and Europe (the CAPACITY trials). In the Japanese trial, pirfenidone significantly reduced decline in VC at week 52 [29]; however, results from the two CAPACITY trials were conflicting. The primary endpoint (change from baseline FVC (% predicted) at week 72) was met in CAPACITY 2 but not in CAPACITY 1 [30]. The reason for these discordant efficacy results was unknown and the US Food and Drug Administration requested an additional randomised, placebo-controlled trial to confirm the effectiveness of pirfenidone in patients with IPF. In the ASCEND trial, treatment with pirfenidone for 52 weeks significantly reduced decline in FVC (% predicted) compared with a placebo (table 1) and had a safety and tolerability profile consistent with previous trials (characterised predominantly by gastrointestinal adverse events and rash) [31]. Subgroup analyses of pooled data from the CAPACITY and ASCEND trials indicated a consistent effect for pirfenidone across patient subgroups defined by a number of baseline characteristics [56]. Results from a pooled analysis of data from the Japanese, CAPACITY and ASCEND trials demonstrated a reduction in all-cause mortality with pirfenidone versus a placebo (relative risk: 0.70; 95% CI: 0.47–1.02) [36]. Pirfenidone has been approved as a treatment for IPF in several countries and regions and received a conditional recommendation in the most recent clinical practice guidelines (table 2) [36].

Lesson learned: reduces disease progression in patients with idiopathic pulmonary fibrosis with a manageable safety and tolerability profile

Nintedanib is an intracellular inhibitor of tyrosine kinases involved in the pathogenesis of IPF, including vascular endothelial growth factor receptor, fibroblast growth factor receptor and platelet-derived growth factor receptor [57–59]. It has demonstrated antifibrotic and anti-inflammatory effects in in vitroexperiments and in animal models [58–60]. The efficacy and safety of nintedanib in patients with IPF were investigated in the Phase-II randomised, placebo-controlled, dose-finding TOMORROW trial. This trial showed that nintedanib (150 mg twice daily over 52 weeks) was associated with a reduced annual decline in FVC, fewer acute exacerbations and preservation of health-related quality of life (as measured using the SGRQ) versus a placebo [32]. In the two replicate, randomised, placebo-controlled, Phase-III INPULSIS trials, nintedanib (150 mg twice daily) significantly reduced the annual rate of decline in FVC versus a placebo. Furthermore, significant benefits were observed for nintedanib versus a placebo with respect to key secondary endpoints (time to first-investigator-reported acute exacerbation and change from baseline in SGRQ total score) in INPULSIS-2 but not in INPULSIS-1 [33]. The most frequent adverse event was diarrhoea, which was manageable for most patients. Subgroup analyses of pooled data from the INPULSIS trials showed that nintedanib had consistent effects across subgroups of patients defined by a variety of baseline characteristics, including lung function and diagnostic criteria (including honeycombing on HRCT and/or confirmation of usual interstitial pneumonia (UIP) by biopsy versus possible UIP and traction bronchiectasis on HRCT and no surgical lung biopsy) [61–63]. In a pooled analysis of data from the TOMORROW and INPULSIS trials, nintedanib reduced the risk of all-cause mortality compared with a placebo (relative risk: 0.70; 95% CI: 0.47–1.03]) [36]. Nintedanib has been approved as a treatment for IPF in several countries and regions and received a conditional recommendation in the most recent clinical practice guidelines (table 2) [36].