Nizar I. Mourad

Progress in Clinical Encapsulated Islet Xenotransplantation.

At the 2015 combined congress of the Cell Transplant Society, International Pancreas and Islet Transplant Association, and International Xenotransplantation Association, a symposium was held to discuss recent progress in pig islet xenotransplantation. The presentations focused on 5 major topics - (1) the results of 2 recent clinical trials of encapsulated pig islet transplantation, (2) the inflammatory response to encapsulated pig islets, (3) methods to improve the secretion of insulin by pig islets, (4) genetic modifications to the islet-source pigs aimed to protect the islets from the primate immune and/or inflammatory responses, and (5) regulatory aspects of clinical pig islet xenotransplantation. Trials of microencapsulated porcine islet transplantation to treat unstable type 1 diabetic patients have been associated with encouraging preliminary results. Further advances to improve efficacy may include (1) transplantation into a site other than the peritoneal cavity, which might result in better access to blood, oxygen, and nutrients; (2) the development of a more biocompatible capsule and/or the minimization of a foreign body reaction; (3) pig genetic modification to induce a greater secretion of insulin by the islets, and/or to reduce the immune response to islets released from damaged capsules; and (4) reduction of the inflammatory response to the capsules/islets by improvements in the structure of the capsules and/or in genetic engineering of the pigs and/or in some form of drug therapy. Ethical and regulatory frameworks for islet xenotransplantation are already available in several countries, and there is now a wider international perception of the importance of developing an internationally harmonized ethical and regulatory framework.

Characterization of porcine endogenous retrovirus expression in neonatal and adult pig pancreatic islets.

Pig islets represent an alternative to the current modes of treatment for patients with diabetes. However, the concerns over pathogen transmission including that of PERV limit their immediate, widespread usage in humans. It has been previously demonstrated that PERV copy number and particularly expression levels can vary considerably between individuals and within different tissues of a single animal. In general, expression levels have been found to be particularly low in the pancreas compared to other porcine tissues suggesting a reduced risk associated with the use of this tissue. Data regarding this crucial aspect, however, remain limited and little is known about PERV status of islets themselves, which represent the final product to be transplanted. In addition, comparative analysis of the PERV status of neonatal piglets with adults is important as they are increasingly considered as potential islet donors for xenotransplantation.

Xenoislets: porcine pancreatic islets for the treatment of type I diabetes

Purpose of review Porcine islets are being extensively investigated as alternative sources of insulin-secreting cells for transplantation in insulin-dependent diabetic patients. The present review focuses on recent advances in porcine islet transplantation with particular emphasis on new transgenic pig models, islet encapsulation, and biosafety considerations. Recent findings Genetic modifications aimed to reduce islet cell immunogenicity, to prolong their survival, and to improve their secretory function have been reported. Micro- and macroencapsulation of porcine islets should allow their use in the clinic with no or minimal immunosuppression. The risk of porcine endogenous retrovirus transmission is being re-evaluated since no evidence for infection was found in several clinical and preclinical studies. Summary Pig islet xenotransplantation is still a serious contestant in the race for novel treatments for type I diabetes. Adequate pathogen screening, animal selection, and the establishment of microbiological, genetic, and potency release quality controls should increase safety and efficacy of future porcine islets transplantation clinical trials.

Assessment of porcine endogenous retrovirus transmission across an alginate barrier used for the encapsulation of porcine islets.

Subcutaneous implantation of a macroencapsulated patch containing human allogenic islets has been successfully used to alleviate type 1 diabetes mellitus (T1DM) in a human recipient without the need for immunosuppression. The use of encapsulated porcine islets to treat T1DM has also been reported. Although no evidence of pathogen transfer using this technology has been reported to date, we deemed it appropriate to determine if the encapsulation technology would prevent the release of virus, in particular, the porcine endogenous retrovirus (PERV).

Gene Editing, Gene Therapy, and Cell Xenotransplantation: Cell Transplantation Across Species.

Purpose of ReviewCell xenotransplantation has the potential to provide a safe, ethically acceptable, unlimited source for cell replacement therapies. This review focuses on genetic modification strategies aimed to overcome remaining hurdles standing in the way of clinical porcine islet transplantation and to develop neural cell xenotransplantation.Recent FindingsIn addition to previously described genetic modifications aimed to mitigate hyperacute rejection, instant blood-mediated inflammatory reaction, and cell-mediated rejection, new data showing the possibility of increasing porcine islet insulin secretion by transgenesis is an interesting addition to the array of genetically modified pigs available for xenotransplantation. Moreover, combining multiple modifications is possible today thanks to new, improved genomic editing tools.SummaryGenetic modification of large animals, pigs in particular, has come a long way during the last decade. These modifications can help minimize immunological and physiological incompatibilities between porcine and human cells, thus allowing for better tolerance and function of xenocells.

Viral pathogens: What are they and do they matter?

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Long-term culture and in vitro maturation of macroencapsulated adult and neonatal porcine islets

Encapsulated porcine islets could be used to treat type I diabetes without necessitating severe immunosuppression. Islet survival and secretory function in the encapsulation device need to be preserved to ensure efficient insulin output in response to surrounding stimuli. In the present study, we evaluated stimulated insulin secretion from adult and neonatal pig islets seeded on an acellular collagen matrix and encapsulated in alginate during long‐term culture. Pig islets survived longer and secreted more insulin when cultured on acellular porcine dermis compared to human fascia. Islets from neonatal pigs could survive up to 33 weeks in vitro, and their insulin secretion increased during the first 5 weeks of culture in a beta‐cell maturation medium. In fact, by the 4th week of culture, insulin secretion from neonatal islets attained the same level as adult islets and even surpassed it by the 18th week. Our results show that in vitro maturation of encapsulated neonatal porcine islets is possible and can actually compensate the initial low insulin secretion from these islets while allowing enough time to perform complete functional and biosafety characterization of islets before transplantation.

Erratum to: Gene Editing, Gene Therapy, and Cell Xenotransplantation: Cell Transplantation Across Species

Fig. 1 In vivo and in vitro insulin secretion from porcine islets. a, b Glucose (○) and insulin (●) were measured in plasma after intravenous glucose challenge (0.5 mg/kg) in piglets (a) and non-human primates (NHP; b). c In vitro insulin secretion from perifused piglet islets exposed to 1 mM glucose (G1) then stimulated with 15 mM glucose (G15). Potassium channel blocker, tolbutamide (500 μM), then 30 mM KCl (K30) were added to the perifusion medium as indicated on top of the figure. Values are means ± SEM from n = 3–5 intravenous glucose tolerance tests (IVGTTs) and n = 4 different preparations for islet perifusions