Critical islet mass for successful porcine islet autotransplantation.

A major reason for the failure of clinical islet transplantations may be a limited islet mass. The aim of this study was to determine the critical islet mass necessary for normalization of glucose metabolism in a porcine model. Diabetes was induced by total pancreatectomy. The splenic lobe of the pancreas was intraductally distended with UW-solution containing 2.67-3.33 mg/ml collagenase, and the distended pancreas was digested in a continuous digestion filtration device. The islets were purified on a isoosmotic Ficoll-sodium-diatrizoate gradient. The survival period of the diabetic recipients in group 2 and 3 receiving, respectively, a low (2.14+/-0.39 microL/kg body weight) and a high (4.99+/-0.83 microL/kg body weight) islet mass was significantly prolonged compared to that of diabetic recipients in group 1 receiving no islet transplantation. However, the survival period of the recipients in group 2 was not significantly different to that in group 3. Three recipients of an islet mass of >5 microl/kg body weight became normoglycemic (fasting blood glucose <100 mg/dl) for more than two months. Furthermore, the glucose and insulin release reactions to the glucose challenge were comparable to that before pancreatectomy. Contrarily, another five diabetic recipients of an islet mass of <4 microL/kg body weight became a fasting blood glucose level of <200 mg/dl. The glucose and insulin release reactions to the glucose challenge were improved only, but not normalized compared to that before pancreatectomy. The data presented in this study demonstrate that metabolic normalization in pancreatectomized diabetic minipigs can be established by autotransplantation of an islet mass of >5 microl/kg body weight.

Successful islet auto- and allotransplantation in diabetic pigs.

BACKGROUND: Because of its anatomical and physiological similarities to humans, the pig appears to be a suitable large animal model for preclinical studies of islet transplantation. The aim of this study was to investigate islet auto- and allotransplantation in a pig model with diabetes induced by total pancreatectomy. METHODS: Porcine islets were isolated by a continuous digestion-filtration device at 32 degrees C and purified by a discontinuous iso-osmolar Ficoll-sodium-diatrizoate gradient on a Cobe 2991. The purified islets were autografted into the liver or the renal subcapsular space. The liver appears to be a more suitable site for the islet grafts than the renal subcapsular space, and the minimal amount of islets for reversal of diabetes is >5 microl/kg of body weight. RESULTS: Persistent normoglycemia (fasting blood glucose level: 72.4+/-44.38 mg/dl) with a normal insulin secretion response to glucose stimulation was successfully achieved in five of six diabetic pigs by implanting a sufficient islet mass into the liver. Triple-drug immunosuppressive therapy with cyclosporine, azathioprine, and prednisolone did not prevent porcine islet allografts from experiencing early failure. However, the addition of 15-deoxyspergualin to the triple-drug immunosuppressive regimen significantly prolonged the function of the islet allografts. When antithymocyte globulin was added to the above-mentioned immunosuppressive drug regimen, the normoglycemic period was prolonged to more than 1 month (fasting blood glucose level: 75.4+/-17 mg/dl). CONCLUSION: We conclude that autotransplantation with a sufficient islet mass can induce normoglycemia with a normal insulin secretion response to glucose stimulation in pancreatectomized diabetic pigs and that allotransplantation can be successfully achieved when 15-deoxyspergualin and antithymocyte globulin are combined with the triple-drug immunosuppression described above. However, this immunosuppressive protocol results in a high rate of infectious complications.

Biocompatibility and immunology in the encapsulation of islets of Langerhans (bioartificial pancreas).

Successful transplantation of encapsulated islets (bioartificial pancreas) would circumvent problems of islet availability and rejection in the treatment of insulin-dependent diabetes with biological organ replacement. Alginates are widely used as a hydrogel matrix or membrane for immunoprotected transplantation. A major problem in the use of diffusion-based devices is the biocompatibility of the material used. The foreign body reaction after implantation of empty microcapsules into different compartments in rats, dogs and pigs is evaluated in this article. However, biocompatibility of the bioartificial pancreas has three different aspects: reaction of the entrapped islet to the encapsulation technique and material; reaction of the recipient against the incorporated device ( = foreign body reaction); and finally the reaction of the recipient against the encapsulated islet ( = immunology of bioartificial pancreas). It is obvious from different experiments that even if foreign body reactions (reactions against material) are almost abolished the recipient may react against material released from the encapsulated islet. In conclusion, transplantation of encapsulated islets induces various morphological reactions (i.e. inflammation and fibrosis) as a result of a variety of donor and recipient related factors. Therefore, the use of an adequate animal model that reflects the human situation is essential for progress in the development of a bioartificial pancreas.