Survival of microencapsulated islets at 400 days posttransplantation in the omental pouch of NOD mice.

The long-term durability of agarose microencapsulated islets against autoimmunity was evaluated in NOD mice. Islets were isolated from 6-8-week-old prediabetic male NOD mice and microencapsulated in 5% agarose hydrogel. Microencapsulated or nonencapsulated islets were transplanted into the omental pouch of spontaneously diabetic NOD mice. Although the diabetic NOD mice that received nonencapsulated islets experienced a temporary reversal of their hyperglycemic condition, all 10 of these mice returned to hyperglycemia within 3 weeks. In contrast, 9 of 10 mice transplanted with microencapsulated islets maintained normoglycemia for more than 100 days. Islet grafts were removed at 100, 150, 200, 300, and 400 days posttransplantation. A prompt return to hyperglycemia was observed in the mice after graft removal, indicating that the encapsulated islet grafts were responsible for maintaining euglycemia. Histological examination revealed viable islets in the capsules at all time points of graft removal. In addition, beta-cells within the capsules remained well granulated as revealed by the immunohistochemical detection of insulin. No immune cells were detected inside the microcapsules and no morphological irregularities of the microcapsules were observed at any time point, suggesting that the microcapsules successfully protected the islets from cellular immunity. Sufficient vascularization was evident close to the microcapsules. Considerable numbers of islets showed central necrosis at 400 days posttransplantation, although the necrotic islets made up only a small percentage of the islet grafts. Islets with central necrosis also showed abundant insulin production throughout the entire islets, except for the necrotic part. These results demonstrate the long-term durability of agarose microcapsules against autoimmunity in a syngeneic islet transplantation model in NOD mice.

Primary leiomyoma of the liver: report of a case.

We report a case of primary leiomyoma of the liver. A 71-year-old man was admitted for investigation of a mass lesion in his liver, detected on ultrasonography. Computed tomography (CT) showed a solid tumor, 3 cm in diameter, in the caudate lobe of the liver. He underwent partial hepatectomy, and histological findings of the resected specimen revealed the proliferation of spindle cells, which formed a pattern of interlacing bundles, without any evidence of malignancy. The tumor cells were not immunoreactive to c-kit or S-100, but they were immunoreactive to alpha-smooth muscle actin. No other lesion was found elsewhere in the body. Thus, the tumor was diagnosed as a primary leiomyoma of the liver.

Indefinite islet protection from autoimmune destruction in nonobese diabetic mice by agarose microencapsulation without immunosuppression.

BACKGROUND: The recurrence of autoimmunity and allograft rejection act as major barriers to the widespread use of islet transplantation as a cure for type 1 diabetes. The aim of this study was to evaluate the feasibility of immunoisolation by use of an agarose microcapsule to prevent autoimmune recurrence after islet transplantation. METHODS: Highly purified islets were isolated from 6- to 8-week-old prediabetic male nonobese diabetic (NOD) mice and microencapsulated in 5% agarose hydrogel as a semipermeable membrane. Islet function was evaluated by a syngeneic islet transplantation model, in which islets were transplanted into spontaneously diabetic NOD mice. RESULTS: The nonencapsulated islet grafts were destroyed and diabetes recurred within 2 weeks after transplantation in all 12 mice. In contrast, 13 of the 16 mice that underwent transplantation with microencapsulated islets maintained normoglycemia for more than 100 days after islet transplantation. Histologic examination of the nonencapsulated islet grafts showed massive mononuclear cellular infiltration with beta-cell destruction. In contrast, the microencapsulated islets showed well-granulated beta cells with no mononuclear cellular infiltration around the microcapsules or in the accompanying blood capillaries between the microcapsules. CONCLUSIONS: Agarose microcapsules were able to completely protect NOD islet isografts from autoimmune destruction in the syngeneic islet transplantation model.

Xenotransplantation of pig islets in diabetic dogs with use of a microcapsule composed of agarose and polystyrene sulfonic acid mixed gel.

INTRODUCTION: The authors have designed a microcapsule composed of agarose and polystyrene sulfonic acid (PSSa) mixed gel that provides a protective barrier against complement attack. Xenografts of islets, encapsulated in an agarose-PSSa microcapsule, have been shown to normalize blood glucose in rodents with chemically induced diabetes for extended periods of time without immunosuppression. AIM: To investigate the efficacy of agarose-PSSa microencapsulated pig islets in reversing diabetes in a large animal model. METHODOLOGY: Diabetes was induced in beagle recipients by total pancreatectomy. Each recipient received three to five intraperitoneal injections of either encapsulated (n = 5) or nonencapsulated pig islets (n = 2). RESULTS: In all dogs receiving microencapsulated islets, the graft function was achieved for 7.4 +/- 3.1 weeks (mean +/- standard error), as determined by elimination or reduction of exogenous insulin requirement. In three recipients, the fasting blood glucose levels were maintained at < or = 200 mg/dL without any exogenous insulin for a period of 6, 50, and 119 days. Circulating porcine C-peptide was detected in the sera of all dogs after transplantation of encapsulated islets. Immunohistologic examination revealed the presence of insulin-positive cells in the microcapsules. In contrast, in two dogs receiving nonencapsulated islets there was no graft function. CONCLUSIONS: This preliminary study demonstrates that agarose-PSSa microencapsulated pig islets can survive and function for weeks or months in totally pancreatectomized diabetic dogs without immunosuppression.