Tomohito Saito

Restrictive allograft syndrome post lung transplantation is characterized by pleuroparenchymal fibroelastosis

We previously described restrictive allograft syndrome as a form of chronic lung allograft dysfunction, demonstrating restrictive pulmonary function decline. However, the histopathological correlates of restrictive allograft syndrome have yet to be satisfactorily described. We hypothesized that pulmonary pleuroparenchymal fibroelastosis, as has recently been described in bone marrow transplant recipients, may also be present in the lungs of patients with restrictive allograft syndrome. Retrospective review of 493 patients who underwent lung transplantation between 1 January 1996 and 30 June 2009, was conducted. Out of 47 patients with clinical features of restrictive allograft syndrome, 16 had wedge biopsy, re-transplant lung explant, or autopsy lung specimens available for review. All lungs showed varying degrees of pleural fibrosis. Fifteen of 16 showed parenchymal fibroelastosis, characterized by hypocellular collagen deposition with preservation and thickening of the underlying alveolar septal elastic network. The fibroelastosis was predominantly subpleural in distribution, with some cases also showing centrilobular and paraseptal distribution. A sharp demarcation was often seen between areas of fibroelastosis and unaffected lung parenchyma, with fibroblastic foci often present at this interface. Concurrent features of obliterative bronchiolitis were present in 14 cases. Another common finding was the presence of diffuse alveolar damage (13 cases), usually in specimens obtained <1 year after clinical onset of restrictive allograft syndrome. The single specimen in which fibroelastosis was not identified was obtained before the clinical onset of chronic lung allograft dysfunction, and showed features of diffuse alveolar damage. In conclusion, pleuroparenchymal fibroelastosis is a major histopathologic correlate of restrictive allograft syndrome, and was often found concurrently with diffuse alveolar damage. Our findings support a temporal sequence of diffuse alveolar damage followed by the development of pleuroparenchymal fibroelastosis in the histopathologic evolution of restrictive allograft syndrome.

Protein expression profiling predicts graft performance in clinical ex vivo lung perfusion.

OBJECTIVES To study the impact of ex vivo lung perfusion (EVLP) on cytokines, chemokines, and growth factors and their correlation with graft performance either during perfusion or after transplantation. BACKGROUND EVLP is a modern technique that preserves lungs on normothermia in a metabolically active state. The identification of biomarkers during clinical EVLP can contribute to the safe expansion of the donor pool. METHODS High-risk brain death donors and donors after cardiac death underwent 4 to 6 hours EVLP. Using a multiplex magnetic bead array assay, we evaluated analytes in perfusate samples collected at 1 hour and 4 hours of EVLP. Donor lungs were divided into 3 groups: (I) Control: bilateral transplantation with good early outcome [absence of primary graft dysfunction- (PGD) grade 3]; (II) PGD3: bilateral transplantation with PGD grade 3 anytime within 72 hours; (III) Declined: lungs unsuitable for transplantation after EVLP. RESULTS Of 50 cases included in this study, 27 were in Control group, 7 in PGD3, and 16 in Declined. From a total of 51 analytes, 34 were measurable in perfusates. The best marker to differentiate declined lungs from control lungs was stem cell growth factor -β [P < 0.001, AUC (area under the curve) = 0.86] at 1 hour. The best markers to differentiate PGD3 cases from controls were interleukin-8 (P < 0.001, AUC = 0.93) and growth-regulated oncogene-α (P = 0.001, AUC = 0.89) at 4 hours of EVLP. CONCLUSIONS Perfusate protein expression during EVLP can differentiate lungs with good outcome from lungs PGD3 after transplantation. These perfusate biomarkers can be potentially used for more precise donor lung selection improving the outcomes of transplantation.

Impact of CLAD Phenotype on Survival After Lung Retransplantation: A Multicenter Study

Chronic lung allograft dysfunction (CLAD) remains a major problem after lung transplantation with no definitive treatment except redo lung transplantation (re‐LTx) in selected candidates. However, CLAD is not a homogeneous entity and different phenotypes exist. Therefore, we aimed to evaluate the effect of CLAD phenotypes on survival after re‐LTx for CLAD. Patients who underwent re‐LTx for respiratory failure secondary to CLAD in four LTx centers between 2003 and 2013 were included in this retrospective analysis. Bronchiolitis obliterans syndrome (BOS) and restrictive CLAD (rCLAD) were distinguished using pulmonary function, radiology and explant lung histopathology. Patient variables pre‐ and post‐re‐LTx were collected and analyzed. A total of 143 patients underwent re‐LTx for CLAD resulting in 94 BOS (66%) and 49 rCLAD (34%) patients. Unadjusted and adjusted survival after re‐LTx for rCLAD was worse compared to BOS (HR = 2.60, 1.59–4.24; p < 0.0001 and HR = 2.61, 1.51–4.51; p = 0.0006, respectively). Patients waiting at home prior to re‐LTx experienced better survival compared to hospitalized patients (HR 0.40; 0.23–0.72; p = 0.0022). Patients with rCLAD redeveloped CLAD earlier and were more likely to redevelop rCLAD. Survival after re‐LTx for rCLAD is worse compared to BOS. Consequently, re‐LTx for rCLAD should be critically discussed, particularly when additional peri‐operative risk factors are present.

Distinct expression patterns of alveolar "alarmins" in subtypes of chronic lung allograft dysfunction.

The long‐term success of lung transplantation is limited by chronic lung allograft dysfunction (CLAD). The purpose of this study was to investigate the alveolar alarmin profiles in CLAD subtypes, restrictive allograft syndrome (RAS) and bronchiolitis obliterans syndrome (BOS). Bronchoalveolar lavage (BAL) samples were collected from 53 recipients who underwent double lung or heart‐lung transplantation, including patients with RAS (n = 10), BOS (n = 18) and No CLAD (n = 25). Protein levels of alarmins such as S100A8, S100A9, S100A8/A9, S100A12, S100P, high‐mobility group box 1 (HMGB1) and soluble receptor for advanced glycation end products (sRAGE) in BAL fluid were measured. RAS and BOS showed higher expressions of S100A8, S100A8/A9 and S100A12 compared with No CLAD (p < 0.0001, p < 0.0001, p < 0.0001 in RAS vs. No CLAD, p = 0.0006, p = 0.0044, p = 0.0086 in BOS vs. No CLAD, respectively). Moreover, RAS showed greater up‐regulation of S100A9, S100A8/A9, S100A12, S100P and HMGB1 compared with BOS (p = 0.0094, p = 0.038, p = 0.041, p = 0.035 and p = 0.010, respectively). sRAGE did not show significant difference among the three groups (p = 0.174). Our results demonstrate distinct expression patterns of alveolar alarmins in RAS and BOS, suggesting that RAS and BOS may represent biologically different subtypes. Further refinements in biologic profiling will lead to a better understanding of CLAD.

Lentivirus IL‐10 Gene Therapy Down‐Regulates IL‐17 and Attenuates Mouse Orthotopic Lung Allograft Rejection

The purpose of the study was to examine the effect of lentivirus‐mediated IL‐10 gene therapy to target lung allograft rejection in a mouse orthotopic left lung transplantation model. IL‐10 may regulate posttransplant immunity mediated by IL‐17. Lentivirus‐mediated trans‐airway luciferase gene transfer to the donor lung resulted in persistent luciferase activity up to 6 months posttransplant in the isograft (B6 to B6); luciferase activity decreased in minor‐mismatched allograft lungs (B10 to B6) in association with moderate rejection. Fully MHC‐mismatched allograft transplantation (BALB/c to B6) resulted in severe rejection and complete loss of luciferase activity. In minor‐mismatched allografts, IL‐10‐encoding lentivirus gene therapy reduced the acute rejection score compared with the lentivirus‐luciferase control at posttransplant day 28 (3.0 ± 0.6 vs. 2.0 ± 0.6 (mean ± SD); p = 0.025; n = 6/group). IL‐10 gene therapy also significantly reduced gene expression of IL‐17, IL‐23, and retinoic acid‐related orphan receptor (ROR)‐γt without affecting levels of IL‐12 and interferon‐γ (IFN‐γ). Cells expressing IL‐17 were dramatically reduced in the allograft lung. In conclusion, lentivirus‐mediated IL‐10 gene therapy significantly reduced expression of IL‐17 and other associated genes in the transplanted allograft lung and attenuated posttransplant immune responses after orthotopic lung transplantation.

Impact of Cytokine Expression in the Pre‐Implanted Donor Lung on the Development of Chronic Lung Allograft Dysfunction Subtypes

The long‐term success of lung transplantation continues to be challenged by the development of chronic lung allograft dysfunction (CLAD). The purpose of this study was to investigate the relationship between cytokine expression levels in pre‐implanted donor lungs and the posttransplant development of CLAD and its subtypes, bronchiolitis obliterans syndrome (BOS) and restrictive allograft syndrome (RAS). Of 109 patients who underwent bilateral lung or heart–lung transplantation and survived for more than 3 months, 50 BOS, 21 RAS and 38 patients with No CLAD were identified by pulmonary function test results. Using donor lung tissue biopsies sampled from each patient, expression levels of IL‐6, IL‐1β, IL‐8, IL‐10, interferon‐γ and tumor necrosis factor‐α mRNA were measured. IL‐6 expression levels were significantly higher in pre‐implanted lungs of patients that ultimately developed BOS compared to RAS and No CLAD (p = 0.025 and 0.011, respectively). Cox regression analysis demonstrated an association between high IL‐6 expression levels and BOS development (hazard ratio = 4.98; 95% confidence interval = 2.42–10.2, p < 0.001). In conclusion, high IL‐6 mRNA expression levels in pre‐implanted donor lungs were associated with the development of BOS, not RAS. This association further supports the contention that early graft injury impacts on both late graft function and early graft function.

Time-dependent changes in the risk of death in pure bronchiolitis obliterans syndrome (BOS)

BACKGROUND The timing of disease onset may affect the prognosis in chronic lung allograft dysfunction (CLAD). The relationship between the timing of disease onset and the prognosis of CLAD and its sub-types, bronchiolitis obliterans syndrome (BOS) and restrictive allograft syndrome (RAS), was examined. METHODS Clinical records and pulmonary function data of 597 patients who underwent bilateral lung transplantation from 1996 to 2010 and survived for >3 months were examined. RESULTS Among 155 patients with a final diagnosis of BOS, patient survival after disease onset was significantly different according to disease-onset timing (BOS onset/post-BOS median survival: overall/1,438 days; <1 year/511 days; 1-2 years/1,199 days; 2-3 years/1,403 days; >3 years/did not reach median survival; p < 0.0001). The prognosis of RAS was generally poorer than that of BOS (overall post-RAS median survival, 377 days). Treating non-CLAD, CLAD, BOS, and RAS as time-dependent covariates, recipient sex-adjusted and age-adjusted Cox regression analysis demonstrated an overall mortality risk of BOS (reference: no CLAD) of 6.7 (95% confidence interval, 4.6-9.9). However, when patients survived 3 years without CLAD, the mortality risk of subsequent BOS was only 1.9 (95% confidence interval, 0.8-4.4) compared with no CLAD. The number of RAS patients was too small to obtain sufficient power to estimate time-dependent mortality risk. CONCLUSION Late-onset BOS showed a better prognosis than early-onset BOS. Studies that do not distinguish BOS from RAS may overestimate the mortality risk of BOS. Multicenter studies will be required to further elucidate risk factors toward the development of better management strategies for CLAD.

Low-dose computed tomography volumetry for subtyping chronic lung allograft dysfunction.

BACKGROUND The long-term success of lung transplantation is challenged by the development of chronic lung allograft dysfunction (CLAD) and its distinct subtypes of bronchiolitis obliterans syndrome (BOS) and restrictive allograft syndrome (RAS). However, the current diagnostic criteria for CLAD subtypes rely on total lung capacity (TLC), which is not always measured during routine post-transplant assessment. Our aim was to investigate the utility of low-dose 3-dimensional computed tomography (CT) lung volumetry for differentiating RAS from BOS. METHODS This study was a retrospective evaluation of 63 patients who had developed CLAD after bilateral lung or heart‒lung transplantation between 2006 and 2011, including 44 BOS and 19 RAS cases. Median post-transplant follow-up was 65 months in BOS and 27 months in RAS. The median interval between baseline and the disease-onset time-point for CT volumetry was 11 months in both BOS and RAS. Chronologic changes and diagnostic accuracy of CT lung volume (measured as percent of baseline) were investigated. RESULTS RAS showed a significant decrease in CT lung volume at disease onset compared with baseline (mean 3,916 ml vs 3,055 ml when excluding opacities, p < 0.0001), whereas BOS showed no significant post-transplant change (mean 4,318 ml vs 4,396 ml, p = 0.214). The area under the receiver operating characteristic curve of CT lung volume for differentiating RAS from BOS was 0.959 (95% confidence interval 0.912 to 1.01, p < 0.0001) and the calculated accuracy was 0.938 at a threshold of 85%. CONCLUSION In bilateral lung or heart‒lung transplant patients with CLAD, low-dose CT volumetry is a useful tool to differentiate patients who develop RAS from those who develop BOS.

Higher M30 and high mobility group box 1 protein levels in ex vivo lung perfusate are associated with primary graft dysfunction after human lung transplantation

BACKGROUND Ex vivo lung perfusion (EVLP) enables assessment of marginal donor lungs for transplantation, with similar clinical outcomes to conventional lung transplantation. We investigated whether cell death-related proteins in the EVLP perfusate could predict primary graft dysfunction (PGD) after transplantation. METHODS M30 (indicating epithelial apoptosis), M65 (indicating total epithelial cell death), and high mobility group box 1 (HMGB-1, related to cell death and inflammation) protein levels in EVLP perfusate were measured by enzyme-linked immunosorbent assay and correlated with clinical outcomes. RESULTS From 100 sequential EVLP patients, 79 lungs were transplanted. Patients who were bridged with extracorporeal life support (ECLS, n = 6) or who received lobar/single lung (n = 25) were excluded. PGD grade 3 (partial pressure of arterial oxygen/fraction of inspired oxygen <200 or need for ECLS) developed in 11 at any time within 72 hours after transplantation (PGD Group). PGD grade 3 did not develop in 34 patients (Control Group). M30 was significantly higher in the PGD Group than in the Control Group at 1 hour (PGD: 73.3 ± 24.9, control: 53.9 ± 15.9 U/liter; p < 0.01) and at 4 hours (PGD: 137.0 ± 146.6, Control: 72.4 ± 40.0 U/liter; p = 0.046) of EVLP. The increase of HMGB-1 from 1 to 4 hours of EVLP was significantly greater in the PGD Group (PGD: 37.0 ± 25.4, Control: 7.2 ± 16.8 ng/ml; p < 0.001). Higher levels of or a greater increase in M30 and a greater increase in HMGB-1 were associated with higher mortality in Cox regression. CONCLUSIONS Levels of M30 and HMGB-1 in the EVLP perfusate correlate with PGD after lung transplantation and might therefore be useful biomarkers to improve donor lung assessment during EVLP.

Upregulation of alveolar neutrophil enzymes and long pentraxin-3 in human chronic lung allograft dysfunction subtypes

From the Latner Thoracic Surgery Research Laboratories, Department of Surgery, Toronto General Hospital Research Institute, University Health Network, and Institute of Medical Science, Faculty of Medicine, and Division of Respirology, University of Toronto, Toronto, Ontario, Canada; the Department of Thoracic Surgery, Kansai Medical University, Hirakata, Osaka, Japan; and Department of Thoracic Surgery, University of Tokyo Graduate School of Medicine, Hongo, Tokyo, Japan. Disclosures: Authors have nothing to disclose with regard to commercial support. Supported by the Canadian Institutes of Health Research (MOP-190953), Canadian Cystic Fibrosis Foundation (grant 2387), and Ontario Ministry of Research and Innovation (grant GL2-01-019). T.S. was supported by Research Fellowships of the Japan Society for Promotion of Science for Young Scientists. Received for publication Dec 26, 2017; accepted for publication Feb 17, 2018; available ahead of print March 21, 2018. Address for reprints: Shaf Keshavjee, MD, MSc, Toronto General Hospital, 200 Elizabeth St, 9N946, Toronto, Ontario M5G 2C4, Canada (E-mail: shaf.keshavjee@uhn.ca). J Thorac Cardiovasc Surg 2018;155:2774-6 0022-5223/