Role of biobanks in transplantation.

The establishment of bio-banks together with high throughput technologies, such as genomics, transcriptomics and proteomics has opened new frontiers in biomarker discovery and the development of systems biology approaches to identifying key pathways that could be exploited to improve outcomes of solid organ transplantation. One of the major challenges in organ donation has been the lack of access to large scale well characterised material to facilitate projects that aim to characterise injury to donor organs and identify biomarkers. This may have hampered research in the field of organ donation by not allowing researchers to materials of high quality and lower pre-analytical variability. We describe in this manuscript the need for bio-banks in organ donation, research opportunities and the particular challenges in establishing such an initiative.

Past, Present, and Future of Dynamic Kidney and Liver Preservation and Resuscitation.

The increased demand for organs has led to the increased usage of "higher risk" kidney and liver grafts. These grafts from donation after circulatory death or expanded criteria donors are more susceptible to preservation injury and have a higher risk of unfavorable outcomes. Dynamic, instead of static, preservation could allow for organ optimization, offering a platform for viability assessment, active organ repair and resuscitation. Ex situ machine perfusion and in situ regional perfusion in the donor are emerging as potential tools to preserve and resuscitate vulnerable grafts. Preclinical findings have ignited clinical organ preservation research that investigates dynamic preservation, its various modes (continuous, preimplantation) and temperatures (hypo-, sub, or normothermic). This review outlines the current status of dynamic preservation of kidney and liver grafts and describes ongoing research and emerging clinical trials.

Using an Integrated -Omics Approach to Identify Key Cellular Processes That Are Disturbed in the Kidney After Brain Death.

In an era where we are becoming more reliant on vulnerable kidneys for transplantation from older donors, there is an urgent need to understand how brain death leads to kidney dysfunction and, hence, how this can be prevented. Using a rodent model of hemorrhagic stroke and next-generation proteomic and metabolomic technologies, we aimed to delineate which key cellular processes are perturbed in the kidney after brain death. Pathway analysis of the proteomic signature of kidneys from brain-dead donors revealed large-scale changes in mitochondrial proteins that were associated with altered mitochondrial activity and morphological evidence of mitochondrial injury. We identified an increase in a number of glycolytic proteins and lactate production, suggesting a shift toward anaerobic metabolism. Higher amounts of succinate were found in the brain death group, in conjunction with increased markers of oxidative stress. We characterized the responsiveness of hypoxia inducible factors and found this correlated with post-brain death mean arterial pressures. Brain death leads to metabolic disturbances in the kidney and alterations in mitochondrial function and reactive oxygen species generation. This metabolic disturbance and alteration in mitochondrial function may lead to further cellular injury. Conditioning the brain-dead organ donor by altering metabolism could be a novel approach to ameliorate this brain death-induced kidney injury.

The role of hypoxia-inducible factors in organ donation and transplantation: the current perspective and future opportunities.

Hypoxia-inducible factors are the universal cellular oxygen-sensitive transcription factors that activate a number of hypoxia responsive genes, some of which are responsible for protective cellular functions. During organ donation, allografts are exposed to significant periods of hypoxia and ischemia. Exploiting this pathway during donor management and organ preservation could prevent and reduce allograft injury and improve the outcomes of organ transplantation. We review the evidence on this pathway in organ preservation, drawing on experimental studies on donor management and ischemia reperfusion injury focusing on kidney, liver, cardiac and lung transplantation. We review the major technical and experimental challenges in exploring this pathway and suggest potential future avenues for research.

Alemtuzumab and sirolimus in renal transplantation: six-year results of a single-arm prospective pilot study.

mTOR inhibitors avoid calcineurin nephrotoxicity, but sirolimus de novo is associated with unacceptable side effects and higher rejection rates. We have investigated a modified strategy: alemtuzumab induction with tacrolimus and mycophenolate maintenance, switching from tacrolimus to sirolimus at 6 months and stopping mycophenolate at 12 months. Here, we report the 6-year follow-up of 30 patients prospectively recruited to this single-arm pilot study and compare outcomes to a matched contemporaneous control group of 30 patients who received standard induction and calcineurin-inhibitor-based immunosuppression.Six-year patient and graft survival were 83% and 80%(alemtuzumab) versus 77% and 70% (control). Rejection rates in the first 6 months were similar in alemtuzumab (6.6%) and control groups (10%). A higher than expected incidence of rejection in the alemtuzumab group following cessation of mycophenolate at 1 year (17%) was mitigated in later patients by retaining low dose mycophenolate. Mean eGFR was higher in the alemtuzumab group at all time points but not significantly (p»0.16). Tacrolimus levels in the first 6 months were significantly higher in the contemporaneous control group (p<0.001). Alemtuzumab induction with initial treatment with tacrolimus enables conversion to sirolimus without the side effects and incidence of acute rejection seen in earlier protocols.

Novel approaches to preventing ischemia-reperfusion injury during liver transplantation.

Ischemia-reperfusion injury (IRI) results in profound allograft damage during liver transplantation. The process of IRI results in adenosine triphosphatase (ATP) depletion, the production of reactive oxygen species, and progressive tissue destruction. This injury process is accelerated on reperfusion in the recipient. Over the last decade an increasing body of literature has identified a complex interplay of molecular and cellular pathways responsible for causing IRI. This article summarizes recent developments, drawing on preclinical and clinical studies, focusing on how the detrimental effects of IRI can be prevented in liver transplantation. We present a balanced overview on how machine preservation technologies, the coagulation system, antioxidants, cytoprotective agents, cytokines, preservation solutions, and the innate and adaptive immune system can be targeted to prevent IRI in liver transplantation.

Simultaneous pancreas kidney transplantation in the HIV-positive patient.

HIV is no longer an absolute contraindication to solid organ transplantation. However, few reports have been published with regards to pancreas or simultaneous pancreas kidney transplantation in the HIV-positive recipient. We report, to our knowledge, the first simultaneous pancreas kidney transplantation (SPK) performed in an HIV-positive patient in the United Kingdom. We reflect on the article recently published by Miro et al in Transplantation Proceedings and highlight strategies used by our department to prevent drug interactions in these complex patients.