Vitamin E succinate enhances steatotic liver energy status and prevents oxidative damage following ischemia/reperfusion.

We have previously shown that treatment of steatotic livers with vitamin E succinate decreases liver injury and increases survival after ischemia/reperfusion (I/R). It is now understood that compromised energy status is associated with increased injury following liver ischemia in the setting of hepatic steatosis at least partially as a result of increased reactive oxygen species (ROS) and induction of mitochondrial uncoupling protein-2 (UCP2). Given the association between ROS, mitochondrial function, and UCP2, it was our goal to determine whether the protective effects of vitamin E succinate were associated with decreased ROS injury, down-regulation of UCP2, or improvement of ATP levels following I/R. To test this, leptin deficient (ob/ob) mice with steatotic livers that had received other 50 IU of vitamin E succinate supplement per day or control chow for 7 days were subjected to total hepatic ischemia (15 minutes) followed by reperfusion. We measured liver expressions of ATP, glutathione (GSH), and UCP2 as well as mitochondrial DNA damage. Vitamin E treatment decreased hepatic UCP2 expression and increased ATP and GSH levels prior to I/R. These levels were maintained at 1 hour after I/R. At 24 hours, while hepatic UCP2 expression, ATP, and GSH levels were similar to those of mice not receiving vitamin E, mitochondrial DNA damage was blocked. These results revealed that vitamin E succinate decreased hepatic UCP2 expression, reduced oxidative stress, and improved mitochondrial function in mice with steatotic livers before and after I/R, identifying mechanisms of protection in this setting.

Vitamin E succinate reduces ischemia/reperfusion injury in steatotic livers.

Steatotic livers represent a growing proportion of marginal organs available for transplantation. These livers are highly prone to primary nonfunction following transplantation and are therefore routinely turned down for surgery. Given the elevated levels and sensitivity for reactive oxygen species (ROS) in these livers, we evaluated whether pretreatment with a targeted ROS scavenger, vitamin E succinate, increased survival and decreased injury after ischemia/reperfusion (I/R). For this study, ob/ob mice received 50 IU/d vitamin E succinate in supplemented vs control chow for 7 days, and were subjected to 15 minutes of total hepatic ischemia and 24 hours of reperfusion. Treatment resulted in a 5-fold decrease in serum alanine aminotransferase (ALT) levels after reperfusion, mirrored by significant decreases in hepatocellular necrosis. These results suggested that targeted antioxidants such as vitamin E succinate may prove to be highly applicable for the pretreatment of steatotic donor livers, increasing their tolerance for I/R and the transplantation process.

Inflammation blockade improves pancreatic islet function.

Pancreatic islet transplantation can replace insulin-secreting beta cells in patients with diabetes mellitus. However, current methodology for isolating islets from a pancreas only retrieves a portion of the total islets. Within these limited number of islets, nearly 50% of beta cells lose biological function before transplantation. Protecting and improving beta-cell viability and function was the goal of this study. Previously we observed that an anti-inflammatory compound, lisofylline (LSF), protects beta cells from cytotoxicity during diabetes development. In this study, we demonstrated that human islets treated in vitro with LSF retained beta-cell glucose responsiveness and insulin secretion in the presence of multiple proinflammatory cytokines. In addition, LSF treatment in vitro enhanced basal insulin production in beta cells, suggesting that LSF can directly improve beta-cell function. LSF reduced beta-cell apoptosis induced by proinflammatory cytokines by 50%. Importantly, 30% fewer LSF-treated islets were sufficient to achieve insulin independence in a murine islet transplantation model. These results demonstrate the ability of LSF-like compounds to protect and enhance beta-cell function, suggesting the potential of using LSF or its analogs in islet transplantation.

Impact of donor immune cells in pancreatic islet transplantation.

Autoimmune-mediated cytotoxicity may cause pancreatic islet transplant failure, leading to recurrent diabetes. Protection of islet grafts depends on immunosuppressive control, which may also prevent autoimmune recurrence of diabetes. In this study, we compared the survival of syngeneic islet transplants using different strains of donor mice. We observed extended functional survival in the islet grafts from donors lacking the genetic background and potential of autoimmunity. Without immunosuppression, the islet grafts of NOR and immune-deficient NOD. Scid donors functioned up to 3 weeks in syngeneic islet transplants compared to 3-day survivals with the grafts from NOD donors. T-cell proliferation and activation markers, CD44 and CD69, were upregulated in NOD donors, suggesting that T-cell activation had occurred prior to pancreas procurement. Systemic delivery of a recombinant adenoassociated viral vector (AAV) encoding the viral (vIL-10) IL-10 gene (AAV vIL-10) in NOD recipients protected syngeneic islets from autoimmune destruction. Alternatively, pretreatment of NOD donor mice with AAV vIL-10 prolonged islet graft survival in untreated NOD recipients. Both studies indicate the effectiveness of vIL-10 gene therapy in autoimmune regulation. These results suggest that a donor factor may exist in autoimmune-prone donors. Therefore, autoimmune recurrence of diabetes may result from donor immune cells transferred during islet transplantation. The AAV vIL-10 gene therapy suppressed previously activated donor T cells and protected the grafted islets from autoimmune-mediated destruction.

Assessment of human pancreatic islets after long distance transportation.

Pancreatic islet transplantation can replace functional insulin-secreting beta cells for patients with type 1 diabetes. More than 300 patients who have received islet transplantation have returned to a euglycemic condition without using insulin. Therefore, islet transplantation has gained public attention and interest. Unfortunately, shortages in organ donations, suboptional antirejection regimens, and difficulties in islet isolation limit clinical utilization of this therapy. Recently, successful islet transplantation has been reported using a centralized islet isolation facility. The advantage of this experience is that it avoids the high costs in building an isolation facility and maintaining an experienced technical team. However, a private airplane carrier was required for transporting islets back to the transplantation site in a remote hospital. The cost of this specialized transportation was still too high to be considered as a routine procedure. In this study, we report our experience using commercial carriers to deliver isolated human islets from an established isolation facility to a remote medical center.