Hypoxic resistance of hypodermically transplanted pancreatic islets by using cell-absorbable antioxidant Tat-metallothionein.

Subcutaneous site is ideal for clinical islet transplantation because it has the advantage of simple operation procedure under local anesthesia and can be biopsied when needed. However, the transplantation outcomes at subcutaneous site have been disappointing due to hypoxia-induced oxidative stress by poor vascularization. We hypothesized that subcutaneously transplanted islets would have hypoxia resistance by using internalization of metallothionein (MT), an antioxidant scavenging enzyme, which was mediated by fusion between MT and cell penetrating Tat peptide. The Tat-MT was dose-dependently transduced into islets without any damage. Tat-MT-treated islets could be protected from oxidative stress induced by intracellular nitric oxide donor, sodium nitroprusside (SNP). When Tat-MT-treated islets were subcutaneously transplanted into diabetic nude mice, they normally controlled the blood glucose levels without severe fluctuation (median survival time (MST): >30 days), whereas most untreated islets were rejected (MST 17 days). From the intraperitoneal glucose tolerance test 5 days after posttransplantation, glucose responsiveness of Tat-MT-treated islets was similar to that of normal healthy mice, while untreated islets had delayed glucose responsiveness. From the results of immunohistochemical stain, Tat-MT-treated islets had strong anti-insulin positive cells and lower anti-HIF-1α positive cells. However, untreated islets had rare anti-insulin positive cells and strong anti-HIF-1α-positive cells. Collectively, these findings demonstrated that Tat-MT delivery into islet could offer a new strategy for successful islet transplantation under subcutaneous space.

MRI of transplanted surface-labeled pancreatic islets with heparinized superparamagnetic iron oxide nanoparticles.

Transplantation of insulin-secreting pancreatic islets can provide real-time regulation of blood glucose in patients with type 1 diabetes mellitus. Currently, noninvasive and repetitive monitoring of islet engraftment and function is an emerging and promising modality for successful islet transplantation. Here we report a new technique for highly sensitive in vivo magnetic resonance (MR) imaging of transplanted pancreatic islets. To this end, heparinized superparamagnetic iron oxide (heparin-SPIO) nanoparticle was newly synthesized for chemical conjugation onto islet surface. Compared to typical cellular labeling of Feridex(®) via random endocytosis, chemical conjugation of heparin-SPIO was stable and improved the hypointensity of transplanted islets due to surface modification of every islet. These heparin-SPIO-conjugated islets showed normal viability and insulin secretion, and were quantified by spin echo T(2)-weighted MR imaging with linear correlation depending on transplanted islet mass in vitro and in vivo for 30 days. Also, from the immunohistochemistry, we confirmed the existence of heparin-SPIO and insulin biosynthesis in transplanted islets. However, Feridex-uptake islets showed late glucose responsiveness according to changing glucose concentration although they could normally control the blood glucose levels in diabetic mouse. Thus, we anticipate that this surface labeling with heparin-SPIO can be directly applicable for MR imaging of transplanted islets.