Double lung, unlike single lung transplantation might provide a protective effect on mortality and bronchiolitis obliterans syndrome

Chronic lung allograft dysfunction (CLAD) remains the major barrier to long-term success after lung transplantation [1‐3]. The primary cause of death after LTx is CLAD. The development of CLAD is rare in the first year after LTx, but the rate increases quickly with cumulative incidence reported to be as high as 40% to 80% within the first five years [4‐7]. CLAD that manifests early after transplantation reportedly shows a poorer prognosis than late-onset CLAD. Bronchiolitis obliterans (BO) is the pathologic pattern of injury most commonly seen in lung transplant recipients with progressive loss of lung function. It is believed to be due to chronic allograft rejection and is characterized by the obliteration of small airways by fibromyxoid granulation tissue. Distribution is patchy and difficult to detect with transbronchial biopsy [3, 7]. Because BO is difficult to document histologically, the International Society for Heart and Lung Transplantation (ISHLT) in 1993 established criteria for its physiologic counterpart, bronchiolitis obliterans syndrome (BOS). This diagnosis requires a permanent 20% drop in the forced expiratory volume in 1 s (FEV1) not attributable to a concurrent process [8]. Since 2014 the diagnosis for chronic rejection was further broadened to CLAD, which includes restrictive allograft syndrome (RAS). CLAD can also be diagnosed by CT scan with visual signs of small airway disease and lung biopsies with severe narrowing or complete obstruction of the small airways [8].

In Sweden two centers perform lung transplantation for a population of about 10 million, all of whom are covered by national health insurance. Skåne University Hospital is one of these centers. This retrospective report reviews the 25-year experience of Skåne University Hospital, Lund University Lung Transplant Program with particular emphasis on chronic rejection between different subgroups of recipients and type of transplant procedure performed. Because of the retrospective nature of this study, chronic rejection is referred to as BOS rather than the recently termed CLAD.

Between January 1990 to June 2014, 278 patients underwent lung transplantation at Skåne University Hospital, Lund University. Double lung transplantation (DLTx) was performed in 172 patients, single lung transplantation (SLTx) in 97 patients, and HLTx in 9 patients. Of these, 129 were male and 149 were female. Re-lung transplantation (Re-LTx) was performed in 15 patients. Among the Re-LTx recipients, of whom 5 were female and 10 were male, 7 recipients had a DLTx and 8 had a SLTx.

In the present study the median age was 51 years with a range of 12–71 years. The major indications were defined as chronic obstructive pulmonary disease (COPD) (n = 67), cystic fibrosis (CF) (n = 54), α1-antitrypsin deficiency (AAT1) (n = 55), pulmonary fibrosis (PF) (n = 38), pulmonary hypertension (PH) (n = 39), and a group deemed as “other” (n = 25), which included bronchiectasis, sarcoidosis, bronchioalveolary cancer, silicosis, and graft-vs-host disease (GVHD).

HLTx was performed via median sternotomy in 7 patients and via a clamshell (bilateral anterolateral thoracotomy with a transverse sternotomy) incision in the 4th intercostal space in 2 patients. SLTx and DLTx were performed in standard fashion. SLTx was performed through a posterolateral thoracotomy in 86 patients, via clamshell in 7 patients, and via median sternotomy in 4 patients. DLTx was performed through a clamshell-incision in 146 patients, via median sternotomy in 17 patients, and via anterolateral thoracotomy in 9 patients.

Preoperative respiratory support was used in 13 operations (CF 4, PF 5, Re-LTx 3, PH 1). Preoperative ECMO (extracorporeal membrane oxygenation) support was used in 12 operations (CF 6, PF 3, ARDS 1, PH 1, Re-LTx 1).

Intraoperative circulatory support in the form of extracorporeal circulation (ECC) was used in 105 cases, and intraoperative ECMO was used in 73 cases. Intraoperative circulatory support was not used in 115 cases. Recipient characteristics are shown in Table 1.

Lung transplantation is an established treatment for end stage pulmonary disease [10]. The number of clinical lung transplantation is limited by the shortage of organs, which have resulted in a constant searching for new ways to increase the number of organs [11‐14], while survival after lung transplantation mainly limited by CLAD. Survival after lung transplantation has improved significantly over the last decade, however, CLAD, predominantly manifesting as BOS, remains the primary cause of morbidity and mortality after LTx. Although the risk of developing BOS within the first year is low, cumulative incidence of BOS quickly increases within the first five years [9, 15, 16].

The risk factors for BOS are still not fully understood [17]. Anti-human leukocyte antigen (HLA) donor-specific antibodies (DSA) have been associated with early and high-grade BOS and death after LTx in some studies but is still controversial [18, 19]. Treatments to remove antibodies or limit antibody-mediated damage using plasmapheresis have been shown to have some effect when DSA are first detected. However, the impact of this treatment on clinical outcome following LTx remains unclear [20]. Bacterial and viral infection has also been identified as a possible trigger of BOS after LTx [21, 22]. Although BOS was generally thought to be irreversible, recent evidence suggests that some patients with BOS may respond to azithromycin with an improvement of their FEV1 with more than 10% [22]. In addition, another form of chronic rejection, restrictive allograft syndrome (RAS), has recently been described, which does not fit the BOS definition but is instead characterized by restrictive functional changes involving peripheral lung pathology, leading to the introduction of the more encompassing term CLAD [5, 23].

The overall cumulative incidence of BOS grade ≥ 2 among our 278 recipients was 15% after 5 years, 26% after 10-years, 30% after 15-years, and 32% after 20 years post-transplant. The incidence of BOS was highest among the group referred to as “other”. This group describes a heterogenic group of patients who underwent LTx due to bronchiectasis, sarcoidosis, bronchioalveolary cancer, silicosis, BOS, and graft-vs-host disease (GVHD) that might reflect the high incidence of BOS. The group’s heterogenic appearance makes it difficult to draw any conclusions. Besides the group “other,” the highest incidence of BOS was seen among PF recipients followed by CF, COPD, PH, and AAT1 recipients in the described descending order. It has been shown that BOS and PF respectively exhibit similar disease characteristics with overlapping pathophysiology such as epithelial cell injury and increase in production/deposition of ECM [24]. This patient group is of great interest as the identification of biomarkers in PF could contribute to finding new means of earlier finding BOS [25]. The highest mortality was seen among COPD recipients followed by PH, AAT1, PF, and CF recipients in the described descending order, indicating that CF and PF recipients have a better chance of survival despite developing BOS compared to the other major indications such as COPD and PH. However, it should also be acknowledged that patient outcome among LTx-recipients in Sweden might differ in comparison to other countries such as the US due to a significantly higher incidence of COPD/CF vs. interstitial lung disease, in combination with Sweden having younger recipients [26]. As well as reports from the ISHLT showing almost double the incidence of interstitial lung disease in LTx in comparison to Sweden.

When we compared the different patient groups (pairs of two) of major indications between each other, the group referred to as “other” had significantly higher risk of developing BOS (grade ≥ 2) compared to COPD, AAT1, and PH recipients, keeping in mind that this group of recipients reflects a heterogeneous group of patients where some of the recipients underwent LTx due to BOS and GVHD and where the recipients probably already at the time of transplantation have an immunologic response that might lead to the development of BOS in the pulmonary graft.

Recipients with CF had a significantly higher risk of developing BOS compared to AAT1 recipients, but AAT1 had a significantly higher mortality rate, indicating that CF recipients might withstand the development of BOS better than AAT1 recipients. This finding could have a positive effect on the clinical implication of favoring CF recipients in LTx. Previously the overall survival benefit of LTx in CF has been reported as controversial due to associated risk factors such as CF-related arthropathy as well as associated chronic infections with bacterial/fungal agents like B.cepacia, P.Auriginosa and Aspergillus that can be serious and life-threatening [27]. Interestingly, recipients with CF had a significantly higher risk of developing BOS compared to PH recipients, however, CF and PH recipients had the same mortality, indicating that CF and PH recipients developing BOS have the same chance of survival despite BOS. It has been shown that PH patients undergo extensive remodeling of the pulmonary arterial walls as part of their pathophysiology, leading to permanent changes of the intima [28]. However, PH is also seen post-LTx among different recipients as bronchiolitis obliterans is often associated with immune-mediated arterio- and venopathy leading to pre- and post-capillary PH [29]. It could be theorized that patients with PH prior to LTx might better withstand this phenomenon, indicating why PH recipients don’t show inferior survival to CF despite BOS. The clinical implication of understanding the development of BOS in this disease state could be of immense potential. This hypothesis was however not investigated in this study with the need of further data.

Interestingly, when we compared DLTx to SLTx in the entire cohort we found that DLTx and SLTx recipients had equal risk of developing BOS grade ≥ 2. However, recipients receiving DLTx had a significantly better chance of surviving. These results further support a clinical program favoring DLTx instead of SLTx. We tried to analyze the pattern of DLTx and SLTx among major indications such as COPD, but unfortunately the groups were not big enough to reach statistical evaluation. Our findings indicate that DLTx and SLTx had the same risk of developing BOS, but DLTx had a better chance of survival. We suspect that these results might reflect the fact that during the last 10–15 years, we have initiated early treatment for viral and bacterial infection, used more aggressive therapy at the first sign of rejection, and favored DLTx over SLTx. The frequency of SLTx reached its peak in 2002 at our clinic and has significantly declined since then in favor of DLTx. However, our results did not support these hypotheses as no difference was found between the risk of BOS or mortality in different time periods. In Fig. 5 we show the results for the two different time periods 1990–2002 and 2003–2014.

No differences were seen in the incidence of BOS grade ≥ 2 regarding type of transplant, however, DLTx recipients showed a better chance of survival despite the same risk for developing BOS compared to SLTx recipients, indicating that recipients receiving DLTx withstand BOS better than SLTx. These figures further support a clinical program favoring DLTx instead of SLTx. The highest incidence of BOS grade ≥ 2 was seen among PF, CF, COPD, PH, and AAT1 recipients in descending order described where PF recipients had the highest risk of developing BOS. However, CF and PF recipients showed a better chance of survival despite developing BOS compared to COPD, PH, and AAT1 recipients.