Sustained zero-order delivery of GC-1 from a nanochannel membrane device alleviates metabolic syndrome.

BACKGROUND/OBJECTIVES: Our objective was to assess the sustained, low-dose and constant administration of the thyroid receptor-ß (TRß)-selective agonist GC-1 (sobetirome) from a novel nanochannel membrane device (NMD) for drug delivery. As it known to speed up metabolism, accomplish weight loss, improve cholesterol levels and possess anti-diabetic effects, GC-1 was steadily administered by our NMD, consisting of an implantable nanochannel membrane, as an alternative to conventional daily administration, which is subject to compliance issues in clinical settings. SUBJECTS/METHODS: Diet-induced obese C57BL/J6 male mice were fed a very high-fat diet (VHFD) and received NMD implants subcutaneously. Ten mice per group received capsules containing GC-1 or phosphate-buffered saline (control). Weight, lean and fat mass, as well as cholesterol, triglycerides, insulin and glucose, were monitored for 24 days. After treatment, plasma levels of thyroid-stimulating hormone (TSH) and thyroxine were compared. mRNA levels of a panel of thermogenic markers were examined using real-time PCR in white adipose tissue (WAT) and brown adipose tissue (BAT). Adipose tissue, liver and local inflammatory response to the implant were examined histologically. Pancreatic islet number and ß-cell area were assessed. RESULTS: GC-1 released from the NMD reversed VHFD-induced obesity and normalized serum cholesterol and glycemia. Significant reductions in body weight and fat mass were observed within 10 days, whereas reductions in serum cholesterol and glucose levels were seen within 7 days. The significant decrease in TSH was consistent with TRß selectivity for GC-1. Levels of transcript for Ucp1 and thermogenic genes PGC1a, Cidea, Dio2 and Cox5a showed significant upregulation in WAT in NMD-GC-1-treated mice, but decreased in BAT. Although mice treated by NMD-GC-1 showed a similar number of pancreatic islets, they exhibited significant increase in ß-cell area. CONCLUSIONS: Our data demonstrate that the NMD implant achieves steady administration of GC-1, offering an effective and tightly controlled molecular delivery system for treatment of obesity and metabolic disease, thereby addressing compliance.

Prospects for future advancements in islet cell transplantation.

Islet cell transplantation holds great promise for treating patients with type 1 diabetes mellitus (T1DM), and for preventing unstable metabolic state commonly refereed to as brittle diabetes in patients that undergo pancreatic resection given that it is a relatively noninvasive procedure and an attractive alternative to pancreas transplantation for restoring endogenous insulin secretion. The success of recent clinical trials for allogeneic islet transplantation as well as the increasing centers that perform auto-transplantation is showing that the beta cell replacement therapy for the treatment of patients with diabetes or total pancreatectomy has been firmly established. It needs only to be improved and made more widely available to the millions of desperate patients who search for alternatives to a life of insulin injections, hypoglycemia and the risks of end-organ damage. Steady progress has been achieved in recent years in different areas in the pancreatic islet transplantation process including islet cell processing, preservation, and immune therapies that justify optimism. To implement this therapeutic approach to larger cohorts of patients that would benefit from the restoration of beta cell function requires multiple interventions and the standardization of the different stages of islet transplant process. This article will review the possible areas of intervention and the ongoing research toward this important goal.

Serial peripheral blood cytotoxic lymphocyte gene expression measurements for prediction of pancreas transplant rejection.

Acute rejection after pancreas transplantation remains a significant problem and contributes to immunological graft loss. No clinical markers of pancreas rejection have been universally accepted. The purpose of this study was to investigate the use of genetic markers; granzyme B, perforin, and HLA-DRA in the peripheral blood of pancreas transplant recipients. These genes have been identified in renal and islet cell transplant recipients as noninvasive tools to predict acute rejection. Blood samples were collected weekly for up to 1 year posttransplant. Surveillance biopsies of the pancreas were scheduled at weeks 2, 4, 8, and 12 as part of the typical posttransplant protocol for patients with pancreas alone or pancreas after kidney transplantation. Exclusion criteria included a diagnosis of biopsy-proven chronic rejection alone, pancreatitis, or kidney rejection within 2 months after pancreas biopsy. Gene expression levels of granzyme B, perforin, and HLA-DRA were compared in patients with (n = 7) and without biopsy proven acute rejection (n = 7). Recipients with acute rejection showed increased expression of granzyme B, HLA-DRA, as well as perforin genes compared to patients without biopsy-proven rejection. In addition, we observed that elevation of these genes occurred as early as 4 weeks before the traditional biopsy diagnosis, while the recipients with no rejection showed no change in gene expression. Our data indicated that serial measurements of peripheral blood granzyme B, perforin, and HLA-DRA gene expression can be a useful tool to predict pancreas rejection in its earliest stage.

Examination of gene expression profile of functional human pancreatic islets after 2-week culture.

Islet transplant faces significant challenges, mainly because of the high incidence of primary nonfunction of transplanted islets. Protocol modifications to improve the rate of islet function have included changes in pancreatic preservation and the introduction of short-term culture. Islet culture for 48 to 72 hours has become a standard part of most successful protocols for clinical islet transplantation. We have previously reported gene expression profiles associated with human pancreatic islet function. The aim of this study was to determine the change in gene expression profiles of functional islets after 2 weeks of culture in Memphis-serum free media. Human islets from four isolations were maintained in culture for 14 days in Memphis-serum free media. RNA was extracted from 10000 IEQ for analysis of the gene expression profiles using high-density Affymetrix U133A GeneChips and Genespring software. Islet function was assessed by measurements of human C-peptide at days 7 and 14 posttransplant into NOD-SCID mice. Human C-peptide levels were determined by radioimmunoassay. Our preliminary data showed that genes related to functionality, such as those directed toward insulin processing and secretion, did not vary over 14 days of culture, while genes related to exocrine pancreas and organ architecture and immune-associated genes decreased over time. The ability to maintain islets in culture is an important step toward the development of islet tissue repositories, as well as toward screening human islet preparations for additional pathogens.

Changes in abdominal wounds following treatment with sirolimus and steroids in a rat model.

Wound healing complications have been observed in patients receiving sirolimus (SLR). This study examined the degree and duration of delayed healing in various protocols using SLR. Sprague-Dawley rats underwent a standard midline abdominal incision and wound closure. Groups of 6 rats each were randomized to receive different doses of SLR (2 and 5 mg/kg) with or without loading dose (10 mg/kg x3 days), and with or without steroids (20 mg/kg x3 days followed by 5 mg/kg for 2 weeks). Rats were humanely killed on postoperative days 5, 10, or 15. Wound breaking force was measured using the EHMI BIAX-II instrument and tensile strength was calculated. Wounds in control animals had gradual increase in tensile strength during the 15-day observation. In contrast, high and loading doses of SLR caused reduction in wound strength until day 10, but the wounds' tensile strength became equivalent to control by day 15. The addition of steroids prolonged wound recovery with low doses of SLR until day 15 and had very profound effects on healing in high-dose SLR-treated animals (>50% reduction) that continued beyond the 2 weeks of observation. Low doses of SLR in non-steroid-treated animals had a short-term (5-day) impact on wound healing; high dose and loading doses delayed healing for 10 to 15 days. The addition of steroids had a synergistic effect on delayed wound healing, particularly in animals receiving high-dose SLR, which demonstrated prolonged wound weakness. These results may provide practical guidelines for postoperative introduction of SLR in the context of various clinical protocols.

Assessment of human islet viability using various mouse models.

To date no in vitro viability test is known to accurately predict in vivo human islet function, making transplantation into various nonimmune animal models mandatory. The diabetic mouse model has been proposed as a standard method for human islet viability assessment. However, the use of streptozotocin for diabetes induction is associated with inconsistency with respect to induction protocols and the significant mortality rate. The purpose of this study was to compare a nondiabetic NOD-scid mouse model to its diabetic counterpart in terms of predicting islet viability. Diabetes was induced in NOD-scid mice using intraperitoneal injection of streptozotocin at concentrations ranging from 100 to 200 mg/kg. Blood glucose levels were monitored for 7 to 10 days, and mice that had levels of >300 mg/dL were used in the experiment. For nondiabetic mice, blood glucose and baseline human C-peptide levels were checked after an overnight fast. Transplantation of 2000 human islet equivalent was done in both models using the same technique. Islet function was determined in the diabetic mice by return to normoglycemia for 2 consecutive days and measurement of fasting human C-peptide on days 7 and 14 posttransplant. Viability was tested in nondiabetic mice after intraperitoneal injection of glucose (2 g/kg) and the measurement of human C-peptide levels using radioimmunoassay. Titration of the streptozotocin dose from 200 to 100 mg/kg showed a significant reduction in mice mortality (40% to 10%) and an increase of diabetes induction (55% to 81%). The 23 human islet isolations tested in both models showed complete consistency of the viability results.

OP-142 gene expression profile of nonfunctional human pancreatic islets: predictors of transplant failure?

Islet culture has become a standard part of most successful protocols for clinical islet transplantation. To date, however, islets are transplanted based on crude measures of viability, purity and in vitro insulin production without adequate prior assessment of the potential for in vivo function. The purpose of this study was to define the gene expression profiles of human islets associated with in vivo function using a nonimmune NOD-scid mouse model. Human islets from eight isolations were maintained in culture for 7 to 14 days in Memphis serum-free media until transplanted. The RNA was extracted from 10,000 IEQ using RNASTAT-60. The gene expression profiles were analyzed using high-density Affymetrix U133A GeneChips and Genespring software. An aliquot of 2000 IEQ from each islet preparation was also transplanted into NOD-scid animals (n = 5) for in vivo function assessments. Islet function was assessed by measurements of human C-peptide at days 7 and 14 posttransplant. Human C-peptide levels were determined by radioimmunoassay. Gene analysis of nonfunction islets (4 of 8 islet preparations) showed high relative levels of expression of proinflammatory genes and low relative levels of genes directed toward insulin processing and secretion as well as islet integrity. Overexpression of hypoxia and proinflammatory genes may result in reduced insulin secretion and lead to islet destruction posttransplantation. Identifying and validating those genes could allow the development of a potency assay for human transplantation that would be very useful for screening human islet preparations before clinical transplant.

Improved in vivo pancreatic islet function after prolonged in vitro islet culture.

BACKGROUND: Difficulties with recovering and preserving pancreatic islets have hampered progress in islet transplantation. In previous in vitro studies, our laboratory successfully demonstrated that using serum-free medium for prolonged pancreatic islet culture allows postculture recovery ratios greater than those obtained with standard media with sustained in vitro islet function. The goal of this study was to determine whether culturing of islets in a modified serum-free medium (M-SFM) would sustain function in vivo. METHODS: Islets were isolated from pancreata procured from 12 cadaveric organ donors and cultured in the M-SFM for up to 2 months, cryopreserved at -70 degrees C within 1-3 days of isolation for 2 months, or placed in short-term culture (3-5 days) before their transplantation under the kidney capsule of nonobese diabetic-severe combined immunodeficient mice (n=4-7 per group/time point). In vivo islet function was assessed by measuring the production of human insulin and C-peptide over a period of 3-15 months. RESULTS: After extended culture of islets in M-SFM for 1 or 2 months, transplanted islets maintained their viability, and in some instances in vivo function improved when compared with short-term cultured islets transplanted from the same preparation (P<0.01). Improvement was particularly evident for islets cultured for 1 month. Furthermore, when compared with cryopreserved preparations, early function (postoperative day 7) of islets from 1-month culture preparations was statistically better (P<0.05). Prolonged culture in M-SFM had no significant impact on long-term function, inasmuch as cultured islets functioned for more than 120 days. CONCLUSION: These data demonstrate that prolonged islet culture in M-SFM sustained viability and function, and in some instances had a positive effect on in vivo islet function, particularly in the 1-month cultures. No negative effect on long-term in vivo function was demonstrated in this study. Confirmation in clinical models utilizing extended (1-2 months) islet culture in M-SFM could significantly enhance islet transplantation by allowing the identification of best-matched recipients, pretransplantation recipient conditioning, and possible pretransplantation islet modifications to promote engraftment and prolonged graft function.

Differences in ICAM-1 and TNF-alpha expression between large single fraction and fractionated irradiation in mouse brain.

PURPOSE: To elucidate the brain molecular response to irradiation. The expression of the intercellular adhesion molecule (ICAM-1) and tumour necrosis factor-alpha (TNF-alpha) in the mouse brain was compared after single-dose and fractionated whole-brain irradiation. MATERIALS AND METHODS: Mice received a single dose of 2, 10 or 20 Gy or a fractionated dose (2 Gy day(-1)) of 10, 20 or 40 Gy. ICAM-1, and TNF-alpha mRNA expression were quantified by the highly sensitive real-time polymerase chain reaction technique. Expression of ICAM-1 protein was quantified by dual-labelled monoclonal antibody assay. RESULTS: After a 20-Gy single dose, there was an increase in ICAM-1 and TNF-alpha mRNA levels (14- and 11-fold, respectively) as well as a significant increase in the level of ICAM-1 protein (p=0.0243). The expression of ICAM-1 and TNF-alpha mRNA increased at the end of the 40-Gy fractionated regimen (3.55- and 2.30-fold, respectively). CONCLUSIONS: The molecular response of the brain to single-dose irradiation was rapid, while its response to fractionated irradiation was slow. This finding is consistent with clinical observations and could be of use when designing strategies to mitigate radiation sequelae.