Monitoring regulatory T cells as a prognostic marker in lung transplantation

Bronchial anastomotic complications as a microvascular disruption in a mouse model of airway transplantation

Lung transplantation (LTx) offers a last resort for patients battling end-stage lung disease. Even though short-term survival has improved, these patients still face several long-term challenges, such as chronic rejection and ischemic bronchial anastomosis. In lung transplant recipients, the bronchial anastomosis is prone to complications-such as poor wound healing, necrosis, stenosis, and dehiscence-due to the marginal blood supply at this site. During peri-LTx, hypoxia and ischemia stimulate fibrotic and inflammatory cytokines at anastomotic sites, leading to abnormal collagen production and excessive granulation, which impair wound healing. Despite meticulous techniques, bronchial anastomosis remains a major cause of morbidity and mortality among lung transplant recipients. After LTx, most bronchial complications are attributed to ischemic insult since normal bronchial blood flow is disrupted, and bronchial revascularization usually takes two to four weeks, making the anastomotic bronchial vessels dependent on pulmonary artery circulation. It is clear that hypoxia, inflammation, oxidative stress, and extracellular matrix remodeling play critical roles in bronchial complications, but there is no small animal model to study them. In the context of LTx, mouse tracheal models are essential tools for studying bronchial complications, particularly ischemia, fibrosis, and stenosis, as well as evaluating potential therapeutic interventions. A well-established mouse model of orthotopic tracheal transplantation (OTT) mimics the anastomosis of the bronchi and the subsequent microvascular injury, providing a pathological correlation with anastomotic complications. A series of previous studies using the OTT model explored the microvascularization, ischemia-reperfusion, airway epithelial injury, and fibrotic remodeling effects after airway anastomosis. This review describes OTT as a model of airway anastomotic complications, which is crucial for understanding the immunological and molecular pathways as seen in clinical bronchial anastomoses, as well as improving anastomotic healing and reducing complications through targeted therapeutic strategies.

Personalized Nanomedicine-Mediated immune regulation for Anti-Rejection in organ transplantation

The advent of personalized medicine and nanomedicine has led to significant advancements in organ transplantation. Personalized medicine leverages individual patient profiles, including genetic, epigenetic, and immune characteristics, to tailor treatment regimens. Nanomedicine, involving the use of nanoparticles and nanotechnology, offers precise drug delivery and innovative diagnostic tools. The integration of personalized nanomedicine into these fields has the potential to revolutionize transplantation by enhancing graft survival, minimizing adverse effects, and achieving immune tolerance. This review explores the current landscape of personalized nanomedicine for organ transplantation, focusing on immune modulation and therapeutic strategies tailored to individual patient profiles. We also discuss future research directions, including large-scale clinical trials, and regulatory considerations. This review concludes by examining the potential of personalized nanomedicine in improving long-term transplant outcomes and enhancing patient quality of life.

Transition from Transbronchial Forceps to Cryobiopsy After Lung Transplantation: A Single-Centre Experience

The gold standard for histological acute cellular rejection diagnosis is transbronchial forceps biopsy (FB), but in recent years, transbronchial cryobiopsy (CB) has been increasingly used. This study aims to compare the diagnostic rate and safety of FBs and CBs performed in two different periods. We retrospectively reviewed our case history for the two biopsy procedures: 251 FBs (223 for surveillance purposes and 28 for clinical indication) and 218 consecutive CBs (159 for surveillance purposes and 59 for clinical indication). All biopsies were scored according to the ISHLT criteria. Diagnostic yield was higher in the CB group for all the parameters considered: a grade of acute rejection (AR) was detected in 95.0% vs. 84.5% in the CB vs. FB groups (p < 0.001). The diagnostic rate of airway inflammation was 65.1% vs. 51.8% (p = 0.005), and 89.0% vs. 64.9% (p < 0.001) for chronic rejection. Pneumothorax requiring chest drainage occurred in 4% of the CB group and 3% of the FB group. Moderate and severe bleeding complicated CB and FB procedures in seven (3%) and three cases (1%), respectively. Transbronchial cryobiopsies improved the diagnostic yield in the monitoring of the lung allograft. The complication rate did not increase significantly in CBs vs. FBs.

Immune aging: biological mechanisms, clinical symptoms, and management in lung transplant recipients

While chronologic age can be precisely defined, clinical manifestations of advanced age occur in different ways and at different rates across individuals. The observed phenotype of advanced age likely reflects a superposition of several biological aging mechanisms which have gained increasing attention as the world contends with an aging population. Even within the immune system, there are multiple age-associated biological mechanisms at play, including telomere dysfunction, epigenetic dysregulation, immune senescence programs, and mitochondrial dysfunction. These biological mechanisms have associated clinical syndromes, such as telomere dysfunction leading to short telomere syndrome (STS), and optimal patient management may require recognition of biologically based aging syndromes. Within the clinical context of lung transplantation, select immune aging mechanisms are particularly pronounced. Indeed, STS is increasingly recognized as an indication for lung transplantation. At the same time, common aging phenotypes may be evoked by the stress of transplantation because lung allografts face a potent immune response, necessitating higher levels of immune suppression and associated toxicities, relative to other solid organs. Age-associated conditions exacerbated by lung transplant include bone marrow suppression, herpes viral infections, liver cirrhosis, hypogammaglobulinemia, frailty, and cancer risk. This review aims to dissect the molecular mechanisms of immune aging and describe their clinical manifestations in the context of lung transplantation. While these mechanisms are more likely to manifest in the context of lung transplantation, this mechanism-based approach to clinical syndromes of immune aging has broad relevance to geriatric medicine.