Prolonged Survival Following Pig-to-Primate Liver Xenotransplantation Utilizing Exogenous Coagulation Factors and Costimulation Blockade.

Since the first attempt of pig-to-primate liver xenotransplantation (LXT) in 1968, survival has been limited. We evaluated a model utilizing α-1,3-galactosyltransferase knockout donors, continuous posttransplant infusion of human prothrombin concentrate complex, and immunosuppression including anti-thymocyte globulin, FK-506, methylprednisone, and costimulation blockade (belatacept, n = 3 or anti-CD40 mAb, n = 1) to extend survival. Baboon 1 remained well until postoperative day (POD) 25, when euthanasia was required because of cholestasis and plantar ulcers. Baboon 2 was euthanized following a seizure on POD 5, despite normal liver function tests (LFTs) and no apparent pathology. Baboon 3 demonstrated initial stable liver function but was euthanized on POD 8 because of worsening LFTs. Pathology revealed C4d positivity, extensive hemorrhagic necrosis, and a focal cytomegalovirus inclusion. Baboon 4 was clinically well with stable LFTs until POD29, when euthanasia was again necessitated by plantar ulcerations and rising LFTs. Final pathology was C4d negative and without evidence of rejection, inflammation, or thrombotic microangiopathy. Thus, nearly 1-mo rejection-free survival has been achieved following LXT in two of four consecutive recipients, demonstrating that the porcine liver can support life in primates for several weeks and has encouraging potential for clinical application as a bridge to allotransplantation for patients with acute-on-chronic or fulminant hepatic failure.

Infection in Organ Transplantation.

The prevention, diagnosis, and management of infectious disease in transplantation are major contributors to improved outcomes in organ transplantation. The risk of serious infections in organ recipients is determined by interactions between the patient's epidemiological exposures and net state of immune suppression. In organ recipients, there is a significant incidence of drug toxicity and a propensity for drug interactions with immunosuppressive agents used to maintain graft function. Thus, every effort must be made to establish specific microbiologic diagnoses to optimize therapy. A timeline can be created to develop a differential diagnosis of infection in transplantation based on common patterns of infectious exposures, immunosuppressive management, and antimicrobial prophylaxis. Application of quantitative molecular microbial assays and advanced antimicrobial therapies have advanced care. Pathogen-specific immunity, genetic polymorphisms in immune responses, and dynamic interactions between the microbiome and the risk of infection are beginning to be explored. The role of infection in the stimulation of alloimmune responses awaits further definition. Major hurdles include the shifting worldwide epidemiology of infections, increasing antimicrobial resistance, suboptimal assays for the microbiologic screening of organ donors, and virus-associated malignancies. Transplant infectious disease remains a key to the clinical and scientific investigation of organ transplantation.

The Cell Biology of Cytomegalovirus: Implications for Transplantation.

Interpretation of clinical data regarding the impact of cytomegalovirus (CMV) infection on allograft function is complicated by the diversity of viral strains and substantial variability of cellular receptors and viral gene expression in different tissues. Variation also exists in nonspecific (monocytes and dendritic cells) and specific (NK cells, antibodies) responses that augment T cell antiviral activities. Innate immune signaling pathways and expanded pools of memory NK cells and γδ T cells also serve to amplify host responses to infection. The clinical impact of specific memory T cell anti-CMV responses that cross-react with graft antigens and alloantigens is uncertain but appears to contribute to graft injury and to the abrogation of allograft tolerance. These responses are modified by diverse immunosuppressive regimens and by underlying host immune deficits. The impact of CMV infection on the transplant recipient reflects cellular changes and corresponding host responses, the convergence of which has been termed the "indirect effects" of CMV infection. Future studies will clarify interactions between CMV infection and allograft injury and will guide interventions that may enhance clinical outcomes in transplantation.

Clinical Implications of Basic Science Discoveries: Immune Homeostasis and the Microbiome-Dietary and Therapeutic Modulation and Implications for Transplantation.

Links between the human microbiome and the innate and adaptive immune systems and their impact on autoimmune and inflammatory diseases are only beginning to be recognized. Characterization of the complex human microbial community is facilitated by culture-independent nucleic acid sequencing tools and bioinformatics systems. Specific organisms and microbial antigens are linked with initiation of innate immune responses that, depending on the context, may be associated with tolerogenic or effector immune responses. Further complexity is introduced by preclinical data that demonstrate the impacts of dietary manipulation on the prevention of genetically determined, systemic autoimmune disorders and on gastrointestinal microbiota. Investigation of interactions of complex microbial populations with the human immune system may provide new targets for clinical management in allotransplantation.

High incidence of xenogenic bone marrow engraftment in pig-to-baboon intra-bone bone marrow transplantation.

Previous attempts of α-1,3-galactocyltransferase knockout (GalTKO) pig bone marrow (BM) transplantation (Tx) into baboons have demonstrated a loss of macro-chimerism within 24 h in most cases. In order to achieve improved engraftment with persistence of peripheral chimerism, we have developed a new strategy of intra-bone BM (IBBM) Tx. Six baboons received GalTKO BM cells, with one-half of the cells transplanted into the bilateral tibiae directly and the remaining cells injected intravenously (IBBM/BM-Tx) with a conditioning immunosuppressive regimen. In order to assess immune responses induced by the combined IBBM/BM-Tx, three recipients received donor SLA-matched GalTKO kidneys in the peri-operative period of IBBM/BM-Tx (Group 1), and the others received kidneys 2 months after IBBM/BM-Tx (Group 2). Peripheral macro-chimerism was continuously detectable for up to 13 days (mean 7.7 days; range 3-13) post-IBBM/BM-Tx and in three animals, macro-chimerism reappeared at days 10, 14 and 21. Pig CFUs, indicating porcine progenitor cell engraftment, were detected in the host BM in four of six recipients on days 14, 15, 19 and 28. In addition, anti-pig unresponsiveness was observed by in vitro assays. GalTKO/pCMV-kidneys survived for extended periods (47 and 60 days). This strategy may provide a potent adjunct for inducing xenogeneic tolerance through BM-Tx.

From the classic concepts to modern practice.

Transplant infectious disease is a field in evolution. For most allograft recipients, immunosuppressive therapies are more potent and have reduced the incidence of acute allograft rejection. At the same time, these therapies have increased susceptibility to many opportunistic infections and virally-mediated malignancies. Immunological tolerance has been achieved in only small numbers of patients who avoid drug toxicities and infection for as long as tolerance persists. The traditional timeline of post-transplant infections remains useful in the development of a differential diagnosis for patients with infectious syndromes. However, patterns of infection in the post-transplant period have changed over the past decade. Recipients are derived from a broader range of socioeconomic and geographical backgrounds. Infections are diagnosed more often, with improved microbiological assays (e.g. nucleic acid testing, NAT) used routinely in the diagnosis and management of common infections and increasingly in the screening of organ donors. Patterns of opportunistic infection have been altered by the increased identification of organisms demonstrating antimicrobial resistance and by the broader use of strategies to prevent viral, bacterial and fungal (including Pneumocystis) infections. Newer techniques are being applied (e.g. HLA-linked tetramer binding, intracellular cytokine staining) to assess pathogen-specific immunity. These are being integrated into clinical practice to assess individual susceptibility to specific infections. Infection, inflammation and the human microbiome are recognized as playing a central role in shaping innate and adaptive immune responses, graft rejection and autoimmunity. The full impact of infection on transplantation is only beginning to be appreciated.

Lamivudine compared with newer antivirals for prophylaxis of hepatitis B core antibody positive livers: a cost-effectiveness analysis.

There is concern over the development of de novo hepatitis B in patients receiving liver transplants from hepatitis B surface antigen negative, hepatitis B core antibody positive donors. Current practice is to place such patients on indefinite lamivudine prophylaxis; however, there is a small risk of breakthrough infection and newer antivirals for hepatitis B are available. The objective of this study was to determine the cost-effectiveness of lamivudine compared with the newer agents, tenofovir and entecavir, in the prophylaxis setting using a Markov model. Three strategies were examined which consisted of either lamivudine or entecavir monoprophylaxis with tenofovir add-on therapy after breakthrough or tenofovir monoprophylaxis with emtricitabine add-on therapy after breakthrough. In the base case scenario, lamivudine was the most cost-effective option at a threshold of $100 000 per quality-adjusted life-year and this remained robust despite parameter uncertainty. Tenofovir had an incremental cost-effectiveness ratio of $3 540 194.77 while other strategies were superior to entecavir therapy. Until drug costs decrease, lamivudine remains the most cost-effective option for hepatitis B prophylaxis in the liver transplant setting.

What's new and what's hot? Basic science at the American Transplant Congress 2012.

Application of advanced molecular techniques and novel animal models has provided new insights into basic mechanisms underlying clinical transplantation. Investigations in diverse areas, including graft rejection and tolerance, autoimmunity and infectious diseases, have revealed increasing complexity of the mechanisms controlling immune function, notably at the interface of the innate and adaptive immune systems and within secondary lymphoid organs. New roles have been identified for NK and dendritic cells, B-lymphocytes and for Th17 and regulatory T cells, notably in novel animal models of costimulatory blockade and tolerance. Confirmation of these observations will be needed in normal animals and in humans undergoing organ and cell transplantation. The impact of the microbiome, of vaccines, and of antimicrobial therapies on immune memory and reconstitution after lymphocyte depletion is beginning to be defined.

Overview: cytomegalovirus and the herpesviruses in transplantation.

Herpesviruses infect most animal species. Infections due to the eight human herpesviruses (HHV) are exacerbated by immunosuppression in organ transplantation. The special features of the herpesvirus life cycle include the ability to establish latent, nonproductive infection and the life-long capacity for reactivation to productive, lytic infection. Interactions between latent virus and the immune system determine the frequency and severity of symptomatic infections. The immunologic and cellular effects of herpesvirus infections contribute to risk for opportunistic infections and graft rejection. Among the most important advances in transplantation are laboratory assays for the diagnosis and monitoring of herpesvirus infections and antiviral agents with improved efficacy in prophylaxis and therapy. For herpes simplex virus, varicella zoster virus and cytomegalovirus, these advances have significantly reduced the morbidity of infection. The syndromes of EBV-associated posttransplant lymphoproliferative disorders (PTLD) and Kaposi's sarcoma remain important complications of immunosuppression. The epidemiology and essential biology of human herpesvirus is reviewed.

New technologies for infectious screening of organ donors.

Viral, bacterial, parasitic, prion, and fungal infections, although uncommon, have been transmitted via organ and tissue allografts. Improved screening techniques for infectious diseases in organ donors have helped to reduce disease transmission. Reports of clusters of donor-derived infections illustrate the need to improve the screening of tissue and organ donors. Available microbiologic assays, including molecular tests, are generally designed for use as diagnostic tools in individuals believed to have a specific infection based on clinical or epidemiological criteria. These assays are frequently unsuitable in the screening of deceased organ donors. Nucleic acid testing may reduce the risk of disease transmission by detecting early-stage infection, including those from human immunodeficiency virus, hepatitis B virus, and hepatitis C virus in the "window" period before antibody seroconversion can be documented. Screening of organ donors for potential pathogens cannot completely exclude the risk of disease transmission. The process of donor screening must continue to evolve with advances in diagnostic technologies for infectious diseases.

Disseminated Mycobacterium kansasii infection with hepatic abscesses in a renal transplant recipient.

Mycobacterium kansasii is the second most frequent cause of non-tuberculous mycobacterial disease in the United States after Mycobacterium avium complex. While primarily it is a pulmonary disease, extrapulmonary manifestations are common. This case report describes a recent renal transplant recipient with disseminated M. kansasii infection presenting with hepatic abscesses, with discussion of clinical management issues and strategies, and a review of the literature.

Retroviral restriction factors and infectious risk in xenotransplantation.

The clinical application of xenotransplantation poses immunologic, ethical, and microbiologic challenges. Significant progress has been made in the investigation of each of these areas. Among concerns regarding infectious risks for human xenograft recipients is the identification in swine of infectious agents including porcine endogenous retroviruses (PERV) that are capable of replication in some human cell lines. PERV replication has, however, been difficult to demonstrate in primate-derived cell lines and in preclinical studies of non-human primates receiving porcine xenografts. Endogenous 'retroviral restriction factors' are intracellular proteins and components of the innate immune system that act at various steps in retroviral replication. Recent studies suggest that some of these factors may have applications in the management of endogenous retroviruses in xenotransplantation. The risks of PERV infection and the potential role of retroviral restriction factors in xenotransplantation are reviewed in detail.

Epidemiology and outcome of invasive fungal infections in solid organ transplant recipients.

Contemporary epidemiology and outcomes of invasive fungal infections (IFIs) in solid organ transplant (SOT) recipients are not well described. From March 2004 through September 2007, proven and probable IFIs were prospectively identified in 17 transplant centers in the United States. A total 429 adult SOT recipients with 515 IFIs were identified; 362 patients received a single and 67 patients received >or=2 organs. Most IFIs were caused by Candida species (59.0%), followed by Aspergillus species (24.8%), Cryptococcus species (7.0%), and other molds (5.8%). Invasive candidiasis (IC) was the most frequently observed IFI in all groups, except for lung recipients where invasive aspergillosis (IA) was the most common IFI (P<0.0001). Almost half of IC cases in liver, heart, and lung transplant recipients occurred during the first 100 days post transplant. Over half of IA cases in lung recipients occurred >1 year post transplant. Overall 12-week mortality was 29.6%; liver recipients had the highest mortality (P=0.05). Organ damage, neutropenia, and administration of corticosteroids were predictors of death. These results extend our knowledge on the epidemiology of IFI in SOT recipients, emphasizing the occurrence of IC early after non-lung transplant, and late complications with molds after lung transplant. Overall survival appears to have improved compared with historical reports.

Viral infection induces de novo lesions of coronary allograft vasculopathy through a natural killer cell-dependent pathway.

Viral infections including those due to cytomegalovirus have been associated with accelerated cardiac allograft vasculopathy (CAV) in clinical trials and some animal models. Evidence demonstrating a direct causal relationship between such infections and de novo formation of coronary vascular lesions is lacking. Heterotopic murine cardiac transplants were performed in a parental to F1 combination in animals lacking both T- and B-lymphocytes (RAG(-/-)). Coronary vasculopathy developed almost exclusively in the presence of recipient infection with lymphocytic choriomeningitis virus but not in uninfected controls. This process was also dependent upon the presence of natural killer (NK) cells as depletion of NK cells abrogated the process. These data show that a viral infection in its native host, and not previously implicated in the production of CAV, can contribute to the development of advanced coronary vascular lesions in cardiac allotransplants in mice. These data also suggest that virus-induced CAV can develop via an NK-cell-dependent pathway in the absence of T- and B-lymphocytes.