Abstract
Introduction No proven treatments exist for bronchiolitis obliterans syndrome (BOS) following lung transplantation. Inhaled liposomal cyclosporine (L-CsA) may prevent BOS progression.
Methods A 48-week phase IIb randomised clinical trial was conducted in 21 lung transplant patients with BOS assigned to either L-CsA with standard-of-care (SOC) oral immunosuppression (L-CsA group) or SOC (SOC-alone group). Efficacy end-points were BOS progression-free survival (defined as absence of ≥20% decline in forced expiratory volume in 1 s (FEV1) from randomisation, re-transplantation or death) and BOS grade change.
Results BOS progression-free survival was 82% for L-CsA versus 50% for SOC-alone (p=0.1) and BOS grade worsened in 18% for L-CsA versus 60% for SOC-alone (p=0.05). Mean changes in ΔFEV1 and forced vital capacity, respectively, stabilised with L-CsA: +0.005 (95% CI −0.004– +0.013) and −0.005 (95% CI −0.015– +0.006) L·month−1, but worsened with SOC-alone: −0.023 (95% CI −0.033– −0.013) and −0.026 (95% CI −0.039– −0.014) L·month−1 (p<0.0001 and p=0.009). Median survival (4.1 versus 2.9 years; p=0.03) and infection rate (45% versus 60%; p=0.7) improved with L-CsA versus SOC-alone; creatinine and tacrolimus levels were similar.
Conclusions L-CsA was well tolerated and stabilised lung function in lung transplant recipients affected by BOS without systemic toxicity, providing a basis for a global phase III trial using L-CsA.
Abstract
Liposomal aerosol cyclosporine (L-CsA) was well tolerated and stabilised lung function in lung transplant recipients affected by BOS. The data provide evidence for an ongoing global phase III trial using L-CsA for BOS. http://bit.ly/2HB8w5j
Introduction
Outcomes after lung transplantation are poor due to bronchiolitis obliterans [1]. Since bronchiolitis obliterans is not readily demonstrated by lung biopsies, the term bronchiolitis obliterans syndrome (BOS) is applied, defined as a sustained forced expiratory volume in 1 s (FEV1) decline [2]. Treatments for bronchiolitis obliterans are poorly efficacious [3–6]. When higher dosages of calcineurin inhibitors are given for improved immunosuppression, nephrotoxicity and opportunistic infections are limiting [7].
Bronchiolitis obliterans is a complex immunological process triggered by a pathogenetic alloresponse leading to epithelial injury, bronchiolar fibro-obliteration and FEV1 decline [8–10], making the bronchiolar epithelium an interventional target. It has been established that inhalational cyclosporine is deposited in peripheral bronchioles in elevated concentrations [11–13].
In rodent and canine orthotopic lung transplant models, inhaled cyclosporine as single-agent therapy prevents histological rejection in a manner comparable to systemic immunosuppression, with higher intragraft cyclosporine concentrations [14–17]. In humans, numerous clinical trials have shown that inhaled cyclosporine can prevent or ameliorate histological rejection and improve lung function [18–28]. FEV1 improvement has been shown to be dependent on the cyclosporine allograft concentration [21, 27, 28]. Previous studies of inhaled cyclosporine relied on propylene glycol to solubilise cyclosporine with a jet nebuliser, which resulted in adverse respiratory symptoms in up to 50% of patients [25]. Better tolerated aerosol formulations with quicker delivery and enhanced bioavailability are needed.
This trial, which used a liposomal formulation of aerosolised cyclosporine A (L-CsA), tailored for fast and targeted drug aerosol delivery with a high-performance nebuliser (eFlow), given in addition to standard-of-care (SOC) oral immunosuppression for the treatment of BOS following lung transplantation, is the first randomised controlled study using L-CsA for BOS treatment.
Methods
Patient characteristics
This open-label randomised trial was conducted at the University of Maryland (Baltimore, MD, USA) with Institutional Review Board approval. This study is registered at ClinicalTrials.gov with identifier number NCT01650545. The trial was conducted by way of the primary author's (A.I.) Investigational New Drug (IND) application. Enrolment was from September 2012 to January 2015. Follow-up for lung function was for 1 year and survival until September 2017.
Patients ≥18 years of age were eligible if recipients of a single or bilateral pulmonary allograft, had clinically diagnosed BOS grade 1 or 2 [2] within 4 weeks of study entry and were receiving tacrolimus-based immunosuppression. Exclusion criteria are listed in the supplementary material. No patient had restrictive chronic lung allograft dysfunction or antibody-mediated rejection prior to or at randomisation, or thereafter [29, 30].
Investigational medicinal product
The product is a drug–device combination: L-CsA and an investigational eFlow nebuliser system (PARI Pharma, Gräfelfing, Germany). L-CsA was supplied in vials of 5 mg/1.25 mL and 10 mg/2.5 mL containing liposomes ∼50 nm diameter (polydispersity index <0.4) after reconstitution. The eFlow nebuliser produces an aerosol in the respirable range (2.8−5 µm). Average inhalation time was 10–15 min.
Treatment regimens
Conventional oral immunosuppression (SOC) included: tacrolimus (0.06 mg·kg−1·day−1), mycophenolate mofetil (2000 mg·day−1) and prednisone (10–20 mg·day−1). Immunosuppression was adjusted per the University of Maryland protocol (supplementary material). Augmented immunosuppression was given for treatment of histological or clinical rejection consisting of corticosteroids (intravenous methylprednisolone 1 g·day−1 (3 days) or oral prednisone at a dose of 100 mg tapered to 10 mg over 14 days) or antithymocyte globulin (ATG) 1.5 mg·kg−1·day−1 (3–5 days).
Patients randomised to the L-CsA arm were scheduled to receive L-CsA twice daily for 24 weeks at doses of 5 mg (single allograft) or 10 mg (double allograft), in addition to SOC. After the initial 24-week treatment period, patients in the L-CsA arm continued on SOC during a subsequent 24-week follow-up. Patients randomised to the SOC-alone arm received standard immunosuppression only.
Trial design and evaluations
The objective of the study was to evaluate safety and efficacy of L-CsA for grade 1 and 2 BOS. Because single lung recipients have a worse outcome, randomisation was stratified according to single and bilateral status. Patients were then randomly assigned to groups according to block randomisation in a 1:1 ratio to receive either L-CsA or SOC-alone. Study treatment began as soon as possible after randomisation, typically within 7 days. If SOC-alone patients met a primary end-point of ≥20% decline in FEV1 from randomisation and still met initial study entry criteria, L-CsA was permitted as “rescue” crossover. Additionally, if this efficacy end-point occurred during the second 24-week follow-up period after L-CsA administration in that arm, L-CsA could then be re-initiated for a second 24-week period. Crossover patients in both arms were followed clinically, but their data were included in the study analyses end-points up until they met a primary study end-point.
End-points
There were two primary end-points: 1) a composite of BOS progression-free survival, defined as time from randomisation to ≥20% decline in FEV1, re-transplantation or death, whichever occurred first (prolonged mechanical ventilation and irreversible respiratory failure equivalent to ≥20% decline of FEV1), and 2) BOS grade progression by grade changes from randomisation to study completion. A decline in FEV1 was validated for absence of concurrent illness measured at intervals ≥3 weeks apart.
Other exploratory end-points included change in lung function, quantitation of histological bronchiolitis obliterans and bronchoalveolar lavage (BAL) cytokine measurements (interleukin (IL)-1β, IL-2, IL-6, IL-8, IL-10, IL-17, interferon (IFN)-γ and tumour necrosis factor (TNF)-α)) by multiplex assay (Luminex 100 system; Luminex, Austin, TX, USA) analysed using Bio-Plex Manager (Bio-Rad, Hercules, CA, USA). BAL was performed before randomisation, at week 24, and when indicated clinically [2].
Safety
Patient and graft survival and adverse events including infections and symptoms related to L-CsA were quantified as an index of safety and compared between study arms. An Outcomes and Safety Committee adjudicated events.
Statistical analysis
As the first phase IIb trial using L-CsA for BOS treatment, the number of patients to be randomised was determined by the availability of L-CsA and other resources. The IND study specified the end-points, safety measures and a 3-year enrolment period of 30 patients. No modifications were made after trial initiation. 15 patients per group was deemed appropriate, as absence of the desired outcomes for L-CsA would discourage future drug development. Enrolment of qualifying recipients was discontinued after 3 years after accrual of 21 subjects. The target enrolment goal was not met due to lower than anticipated enrolment rates. Outcome data collection continued until either a primary outcome event occurred or patients without events completed the study at 48 weeks. Patient and graft survival were monitored until September 2017 as an assessment of safety independent of continuation or discontinuation of L-CsA. Patients were analysed according to the intention-to-treat principle. No patient was lost to follow-up.
End-point events were compared by Kaplan–Meier survival analyses and log-rank testing as specified a priori by our protocol. A p-value of <0.05 indicated statistical significance. Since the patient survival analysis showed nonproportionality, the Renyi statistic was also used. Data are presented with hazard ratios and 95% confidence intervals. For lung function analyses, multivariate linear mixed effects statistical models (PROC MIXED in SAS version 9.1.3; SAS Institute, Cary, NC, USA) were utilised [31]. Secondary end-points included lung function changes, infection rates and survival. For lung function, as pre-specified for single and bilateral lungs, one mixed model was based only on post-randomisation lung function data using a longitudinal regression model, while a second model accounted for intragroup values pre-randomisation adjusting for within-patient trends that could potentially influence post-randomisation function. Changes in cytokine measurements from pre- to post-randomisation were compared using two-way ANOVA from 42 BAL collections (21 in each group). Sirolimus and tacrolimus levels and routine laboratory values were compared using a mixed effects model. A total of 243 pulmonary function tests (122 L-CsA and 121 SOC-alone) and 603 blood samples were analysed.
Results
Patient characteristics
Of 43 patients screened, 17 failed to meet BOS grade criteria and 21 were randomised (11 to L-CsA and 10 to SOC-alone) (figure 1). Baseline characteristics and clinical management of the two groups were similar, although more cytomegalovirus mismatches were randomised to L-CsA (table 1). Mean±sd time to BOS confirmation for L-CsA was comparable to SOC-alone (1391±859 versus 1061±796 days; p=0.41). Forced vital capacity (FVC) decline prior to randomisation for both L-CsA and SOC-alone was similar (−0.025 (95% CI −0.034– −0.015) versus −0.021 (95% CI −0.030– −0.012) L; p=0.69). Azithromycin use, induction cycles, BOS grades and absolute FEV1 decline rates prior to randomisation were all similar (supplementary material). All randomised patients reached the efficacy end-point or completed 48 weeks of follow-up. Both the L-CsA and SOC-alone groups received similar cycles of augmentation of immune suppression after randomisation (three steroid pulses and one ATG cycle). Five patients has positive donor-specific antibody results post-transplantation: two patients in L-CsA and three in SOC-alone (three with human leukocyte antigen class 2 reactivity).
BOS progression
Mean±sd FEV1 changes from baseline maximal values were similar at randomisation for L-CsA versus SOC-alone (−31.2±9% and −31.8±6.8%; p=0.8). BOS progression-free survival was observed in nine out of 11 (82%) patients treated with L-CsA versus five out of 10 (50%) SOC-alone patients (hazard ratio 3.19 (95% CI 0.62–16.50); p=0.1) (figure 2a). Only one L-CsA patient met this primary end-point while receiving L-CsA; the second met the end-point while off L-CsA (following the initial 24-week on-treatment period) and stabilised after L-CsA was resumed (a “rescue” crossover). Of the five end-point occurrences in the SOC-alone group, two patients were re-transplanted, one developed respiratory failure and one out of two patients who crossed over from SOC-alone responded to L-CsA without further interventions. BOS grade progression from randomisation occurred three-fold less commonly in patients receiving L-CsA versus SOC-alone (p=0.05) (figure 2b).
Lung function changes prior to randomisation and after L-CsA
ΔFEV1 post-randomisation demonstrated stability with L-CsA (+0.005 (95% CI −0.004– +0.013) L·month−1) compared with SOC-alone (−0.023 (95% CI −0.033– −0.013) L·month−1; p<0.0001) (figure 3a). Additionally, within randomised groups, ΔFEV1 showed improvement after randomisation to L-CsA compared with deterioration prior to study treatment (ΔFEV1 pre-randomisation −0.021 (95% CI −0.032– −0.011) L·month−1 versus post-randomisation +0.005 (95% CI −0.004– +0.013) L·month−1; p=0.0002). In contrast, patients in the SOC-alone group had continued FEV1 decline post-randomisation comparable to pre-randomisation (ΔFEV1 pre-randomisation −0.028 (95% CI −0.039– −0.018) L·month−1 versus post-randomisation −0.025 (95% CI −0.035– −0.015) L·month−1; p=0.3) (figure 3b).
ΔFVC similarly showed improvement post-randomisation for L-CsA and decline for SOC-alone (L-CsA −0.005 (95% CI −0.015– +0.006) L·month−1 versus SOC-alone −0.026 (95% CI −0.039– −0.014) L·month−1; p=0.009) (figure 3c). For the change in forced expiratory flow at 25–75% of FVC (ΔFEF25–75%), a similar pattern was shown post-randomisation for L-CsA (+0.008 (95% CI −0.015– +0.031) L·month−1) versus SOC-alone (−0.015 (95% CI −0.042– +0.011) L·month−1) (p=0.1) (figure 3d). Of the three subjects for whom L-CsA was administered as a rescue therapy (re-initiated for L-CsA or crossover from SOC-alone), the ΔFEV1 slope after L-CsA rescue at 24 weeks was +0.01 (95% CI 0.003–0.018) L·month−1.
BAL cytokines
Cytokines measured were similar before randomisation between the L-CsA and SOC-alone groups. The following cytokines were significantly different after randomisation in L-CsA versus SOC-alone (median (interquartile range)): IL-2 7.1 (0.5–7.1) versus 48.4 (11.3–55.2) pg·mL−1 (p=0.04), IL-10 3.3 (0–13.0) versus 0 (0–2.5) pg·mL−1 (p=0.04) and IFN-γ 3.8 (0.2–37.6) versus 0.8 (0.7–4.4) pg·mL−1 (p=0.05) (figure 4). IL-1β, IL-6, IL-8, IL-17 and TNF-α showed no significant differences before or during the study.
Systemic immune suppression
Maintenance tacrolimus blood levels and doses and prednisone doses were similar at baseline (table 1) and at study completion for L-CsA and SOC-alone: tacrolimus levels 6.32 (95% CI 4.57–8.07) versus 5.19 (95% CI 3.08–7.30) ng·mL−1 (p=0.4), tacrolimus doses 2.0 (95% CI 1.4–2.7) versus 2.5 (95% CI 1.8–3.1) mg·day−1 (p=0.1) and prednisone doses 11.6 (95% CI 9.0–14.0) versus 9.9 (95% CI 7.0–12.7) mg·day−1 (p=0.3). Augmentation cycles did not differ between the treatment arms before or after randomisation. Sirolimus blood levels were lower in L-CsA compared with SOC-alone at study completion (2.65 (95% CI 0.00–5.73) versus 9.29 (95% CI 7.06–11.51) ng·mL−1; p=0.0007), but were similar at randomisation (table 1).
Histopathology before and after randomisation to L-CsA
Transbronchial biopsies were performed when indicated by the University of Maryland protocol. Prior to randomisation, histology demonstrated four cases with airway rejection in L-CsA cases (two patients B1 and two patients with histological changes suggestive of bronchiolitis obliterans) and only one receiving SOC-alone (one patient with changes suggestive of bronchiolitis obliterans). Post-randomisation, four patients receiving SOC-alone had airway rejection (two patients B2 and two patients B1), whereas two patients receiving L-CsA had B1 airway rejection. One patient receiving L-CsA and two patients receiving SOC-alone experienced grade 1 acute rejection. No patient had histopathological changes consistent with antibody-mediated rejection or positive C4d staining prior to or after randomisation.
Pharmacokinetics
Cyclosporine blood sampling was done for all patients randomised to L-CsA and one crossover patient. Mean±sd maximum cyclosporine blood concentration (Cmax) was 57.42±34.26 ng·mL−1 achieved after 15−30 min (tmax) and the half-life (t1/2) was ∼2 h. At 24 h, mean±sd cyclosporine blood concentration was 1.42±4.91 ng·mL−1.
Adverse events
No adverse event required withdrawal from L-CsA or permanent drug discontinuation. No patient was lost to follow-up. Peak expiratory flow (PEF) at the first dosing was 367.7 L·min−1 prior to inhalation and 327.7 L·min−1 after inhalation (−10.9% decrease). No patients met the pre-specified PEF 20% decline criterion to discontinue L-CsA. Three adverse events were related to L-CsA: conjunctivitis, pharyngitis and productive cough.
Mean creatinine at end of follow-up (week 48) for L-CsA and SOC-alone was 1.52 (95% CI 1.31–1.73) versus 1.65 (95% CI 1.41–1.89) mg·dL−1 (p=0.3). Aspartate transaminase (AST), alanine transaminase (ALT) and bilirubin remained within reference ranges (AST 14–36 U·L−1, ALT 9–52 U·L−1 and bilirubin 0.3–1.2 mg·dL−1) in both arms. Serious adverse events occurred with nearly equal frequency for L-CsA and SOC-alone (22 versus 24 events). Four pneumonia events occurred, all in the SOC-alone group. There was no difference in infection rates: five out of 11 (45%) and six out of 10 (60%) patients in the L-CsA and SOC-alone groups, respectively (p=0.7). No adverse events had a fatal outcome.
Survival for L-CsA patients improved compared with SOC-alone (45% (five out of 11) alive compared with 0% (none out of 10) alive; median 4.1 versus 2.9 years; p=0.03 (Renyi test p=0.07)) (figure 5a). Graft survival (death and re-transplant) was similarly improved: 4.1 years L-CsA versus 2.7 years SOC-alone; six out of 11 treatment failures, one re-transplant; 10 out of 10 treatment failures, three re-transplants (p=0.01) (figure 5b). Causes of death were all chronic allograft rejection with the exception of disseminated skin cancer (L-CsA) and renal failure (SOC-alone).
Discussion
Lung transplant survival is limited and has failed to improve substantially during the past two decades. Bronchiolitis obliterans is a leading cause of death [3]. Inhalation of cyclosporine provides high bronchiolar concentrations and may arrest BOS progression [21]. This initial exploratory randomised controlled open-label trial of L-CsA provides evidence for improvement of BOS defined by the composite end-point, i.e. BOS progression-free survival, with a clinically meaningful improvement at 48 weeks (82% L-CsA versus 50% SOC-alone; p=0.1) and a three-fold arrest of BOS grade progression (p=0.05). Although the difference in BOS progression-free survival was not significant statistically in 21 cases, the clinical magnitude of the benefit, i.e. an absolute difference of 32%, was large. Moreover, comparison of change in BOS grade from randomisation was also impressive, with a two-thirds reduction in L-CsA patients.
L-CsA significantly stabilised FEV1 and FVC compared with SOC-alone. In addition to the intergroup differences in FEV1 decline, the intragroup change in FEV1 slopes differed before and after randomisation in L-CsA, converting from a negative to positive slope; in contrast, SOC-alone controls declined functionally post-randomisation at rates similar to pre-randomisation, demonstrating the characteristic inexorable decline of FEV1 from BOS despite current SOC management without L-CsA [32, 33]. Crossover patients who were off L-CsA but started L-CsA because of ongoing deterioration showed similar FEV1 improvements. Prior investigations of bronchiolitis obliterans using aerosol cyclosporine in propylene glycol, as well as a recent study using inhaled cyclosporine for BOS following haematopoietic stem cell transplantation, have shown similar pulmonary function benefits [20, 26, 34], as have other nonrandomised studies using immunosuppressive therapies for bronchiolitis obliterans [35].
L-CsA resulted in the improvement of long-term survival and graft survival (4.1 versus 2.9 years with SOC-alone), a finding nearly matching an observational cohort study performed at the University of Pittsburgh in the USA in 2005 comparing histological bronchiolitis obliterans patients treated with inhaled cyclosporine to SOC-alone controls (median survival 4.5 versus 2.4 years) [18]. An L-CsA survival benefit was also noted in a randomised double-blind placebo-controlled trial showing bronchiolitis obliterans could be prevented by the addition of aerosolised cyclosporine–propylene glycol [25].
Allograft histology demonstrated reduced severity and frequency of bronchiolar inflammation after L-CsA randomisation but not before randomisation and synchronous levels of IL-2 in BAL were lower in L-CsA cases after but not prior to randomisation [36]. Elevated cyclosporine concentrations in the rejecting lung would explain these findings [21, 28]. Increases in BAL cytokines IFN-γ and IL-10 were also observed in L-CsA patients; IFN-γ regulates cellular proliferation and collagen synthesis, while IL-10 can induce immune tolerance [37, 38].
Although the L-CsA and SOC-alone groups were similar with reference to baseline and subsequent BOS treatments, including tacrolimus exposure, immunosuppressive augmentation cycles and azithromycin use [39], the SOC-alone cohort did have significantly higher sirolimus blood levels consistent with physician-directed attempts to control progressing BOS and lung failure. The drug dose of L-CsA was given twice a day to ensure that the beneficial dose of 5 mg would be deposited in the lung allograft. Pharmacokinetics studies demonstrated a low vascular concentration of cyclosporine. Infections and respiratory infections were similar between groups, and L-CsA offered greatly improved tolerability and reduced treatment time with the eFlow nebuliser (10–15 min) compared with cyclosporine–propylene glycol formulations [25]. With increased experience using L-CsA in larger scale trials, systemic immunosuppressive requirements could lessen, as witnessed by reduced sirolimus exposure in L-CsA patients.
In this small, single-centre trial, the addition of inhaled L-CsA offered a substantial functional benefit without additional toxicity. Due to the exploratory nature of this study, further experience is needed to confirm the magnitude and duration of the observed effects. Patient enrolment for a phase III international multicentre trial using L-CsA for BOS has begun (CliniclaTrials.gov identifiers NCT03657342 and NCT03656926).
Supplementary material
Supplementary Material
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Supplementary material 00167-2019.SUPPLEMENT
Acknowledgements
Jennifer McGrain and Joseph Rinaldi Jr (Dept of Medicine, University of Maryland, Baltimore, MD, USA) provided excellent research coordination and data management support, respectively. The comments of Anthony F. Suffredini (NIH Clinical Center, National Institutes of Health, Bethesda, MD, USA) are gratefully acknowledged, and we thank Si Pham (Mayo Clinic Jacksonville, Jacksonville, FL, USA) for leading the Safety and Monitoring Committee (together with Keshava Rajagopal), and Michelle Ruff (Dept of Medicine, University of Maryland) for excellent administrative assistance.
Footnotes
This article has supplementary material available from openres.ersjournals.com
This study is registered at ClinicalTrials.gov with identifier number NCT01650545. Individual participant data will be available after de-identification, including the study protocol, within the first year after article publication. Investigators who propose to use the data will need to be approved by an independent review committee identified for this purpose, for individual participant data for meta-analyses. Proposals may be submitted up to 24 months following article publication.
Author contributions: A. Iacono, B Griffith and M. Terrin contributed to the conception and design of this study, interpreted results, and performed or assisted with the writing and the final proofing of the article to completion. I. Timofte, K. Rajagopal, M. Wijesinha and N. Murdock formulated specific databases for data interpretation, performed the final statistical analyses and commented on all study results formally, and also revised the manuscript critically for essential intellectual content. All authors gave final approval of the manuscript to be published, and agree to be accountable for data integrity and all other essential aspects.
Support statement: We are grateful to PARI Pharma GmbH for drug and device supply for this investigation, and a research grant to the University of Maryland School of Medicine; the IPF Foundation for nursing support; and the Plylar and Riehl Foundations for generously supporting the Lung Healing Center for overall study support. Funding information for this article has been deposited with the Crossref Funder Registry.
Conflict of interest: A. Iacono reports grants from PARI Pharmaceutical outside the submitted work. In addition, he has a patent for the “Use of Aerosolized Cyclosporine for Prevention and Treatment of Pulmonary Disease” issued and is Chairman for an upcoming phase III trial “Inhaled Liposomal Cyclosporine A (L-CsA) for the treatment of Bronchiolitis Obliterans (BO)”.
Conflict of interest: M. Wijesinha has nothing to disclose.
Conflict of interest: K. Rajagopal has nothing to disclose.
Conflict of interest: N. Murdock has nothing to disclose.
Conflict of interest: I. Timofte has nothing to disclose.
Conflict of interest: B. Griffith has nothing to disclose.
Conflict of interest: M. Terrin has nothing to disclose.
- Received July 2, 2019.
- Accepted August 25, 2019.
- Copyright ©ERS 2019
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