Xenotransplantation of neonatal porcine islets and Sertoli cells into nonimmunosuppressed streptozotocin-induced diabetic rats

The testis has been shown to be a privileged site for transplantation of allogenic islets in rodents, and the testicular cell aggregates are thought to confer this immunologic privilege. Recently, a group in Mexico reported transplantation of cocultured neonatal porcine islets and Sertoli cells resulting in insulin independence in nonimmunosuppressed type 1 diabetes patients. We have transplanted similar islets alone (naked islets) or cocultured islets with Sertoli cells (islet/Sertoli cells) into an omental site and other locations of nonimmunosuppressed, streptozotocin-induced diabetic male Sprague Dawley (SD) rats. Histologic examination showed viable neonatal porcine islets survived in xenografted rodents for at least 2 days, and some glucagon and inhibin stained cells appear to have survived for 4 days posttransplantation. However, histological examination did not demonstrate any difference in xenograft survival in the islets/Sertoli cells mixture compared to naked islets when transplanted into these nonimmunosuppressed diabetic rats.     

Accelerated functional maturation of isolated neonatal porcine cell clusters: in vitro and in vivo results in NOD mice

Neonatal porcine cell clusters (NPCCs) might replace human for transplant in patients with type 1 diabetes mellitus (T1DM). However, these islets are not immediately functional, due to their incomplete maturation/ differentiation. We then have addressed: 1) to assess whether in vitro coculture of islets with homologous Sertoli cells (SC) would shorten NPCCs' functional time lag, by accelerating the beta-cell biological maturation/differentiation; 2) to evaluate metabolic outcome of the SC preincubated, and microencapsulated NPCCs, upon graft into spontaneously diabetic NOD mice. The islets, isolated from < 3 day piglets, were examined in terms of morphology/viability/function and final yield. SC effects on the islet maturation pathways, both in vitro and in vivo, upon microencapsulation in alginate/poly-L-ornithine, and intraperitoneal graft into spontaneously diabetic NOD mice were determined. Double fluorescence immunolabeling showed increase in beta-cell mass for SC+ neonatal porcine islets versus islets alone. In vitro insulin release in response to glucose, as well as mRNA insulin expression, were significantly higher for SC+ neonatal porcine islets compared with control, thereby confirming SC-induced increase in viable and functional beta-cell mass. Graft of microencapsulated SC+ neonatal porcine islets versus encapsulated islets alone resulted in significantly longer remission of hyperglycemia in NOD mice. We have preliminarily shown that the in vitro NPCCs' maturation time lag can dramatically be curtailed by coincubating these islets with SC. Graft of microencapsulated neonatal porcine islets, precultured in Sertoli cells, has been proven successful in correcting hyperglycemia in stringent animal model of spontaneous diabetes.     

Serine-protease inhibition during islet isolation increases islet yield from human pancreases with prolonged ischemia.

BACKGROUND: Islet isolation from the pancreatic tissue matrix remains highly variable. Recent evidence suggests that intrinsic human pancreatic proteases, including trypsin, may inhibit effective collagenase enzymatic activity during islet isolation, thereby impairing the isolation success. In this study we have hypothesized that serine protease inhibition applied during pancreatic digestion, could improve yield and/or functional viability of islets isolated from human pancreases. METHODS: Twelve organ donor pancreases with 12.9+/-0.6 hr cold storage (mean+/-SEM) were perfused via their ducts with Liberase-HI enzyme in the presence (n=6) or absence (n=6) of 0.4 mM Pefabloc. All were then gently dissociated and their purified islets separated with Ficoll density gradient centrifugation. RESULTS: Donor-related factors (age, gender, cold storage time, body mass index, and pancreas weight) did not differ significantly between the two experimental groups. Pefabloc supplementation did not affect the digestion time, islets remaining trapped in exocrine tissue, or final islet purity. Islet recovery was increased in the Pefabloc-treated group (mean+/-SEM yield 323.8+/-80.8 x 10(3) islet equivalents vs. 130.8+/-13.6 x 10(3) islet equivalents, P<0.05). Cellular composition, DNA and insulin content, and insulin secretory activity of the isolated islets was similar. CONCLUSIONS: Inhibition of intrinsic protease activity within pancreases after prolonged cold storage improves isolation of viable islets.     

Transplantation of neonatal porcine islets and sertoli cells into nonimmunosuppressed nonhuman primates

A Mexican group reported transplantation of cocultured neonatal porcine islets and Sertoli cells resulting in insulin independence in nonimmunosuppressed type 1 diabetes patients. We have transplanted similar islets alone (naked islets) or cocultured islets with sertoli cells (islet/sertoli cells) into an omental site and other locations of seven nondiabetic, nonimmunosuppressed, nonhuman primates. Porcine endogenous retrovirus was not detected in recipient blood 8 weeks after porcine islet grafts, and porcine C-peptide was detected at a very low level in all animals. Histology examination failed to demonstrate obviously recognizable islets, but in the animals transplanted with islet/Sertoli cells at the omentum site, there were some surviving glucagons, pan-cytokeratin, and inhibin stained cells at 8 weeks.     

Microencapsulation of cryopreserved islets for transplantation

Purpose: The development of islet banks and of techniques to immunoisolate islets by encapsulation has the potential to overcome the major barriers to the routine use of islet transplants as an alternative to insulin therapy in diabetic patients.Aim: The purpose of this study was to determine the in vitro function of islets stored by cryopreservation prior to microencapsulation.Method: Islets were isolated from the pancreata of Sprague-Dawley rats and stored frozen at −80°C in the presence of cryoprotectants for 1 month. After thawing and overnight culture, they were tested either unencapsulated or after microencapsulation with poly-l-lysine-alginate membrane using an air-jet syringe pump. Islets were tested for response to glucose stimulation using a perifusion procedure.Results: In the unencapsulated islets, the mean ± SEM rate of insulin secretion increased from a basal value of 832 ± 34 to a peak of 1448 ± 138 pg/6 islets/min, p < .01, n = 5) within 10 min of raising the glucose concentration from 3.3 mM (60 mg/dl) to 16.7 mM (300 mg/dl). Similarly, insulin secretion in the microencapsulated islets increased from a basal value of 649 ± 6 to a peak of 1184 ± 100, p < .01, with restoration of basal rate on return of islets to basal perifusion. The characteristics of the response to glucose stimulation of these cryopreserved islets were comparable with those seen in freshly isolated islets.Conclusion: Islets cryopreserved for 1 month retained viability after thawing and microencapsulation.     

Effect of Cryopreservation on the Survival and Function of Murine Islet Isografts and Allografts

We compared the efficacy of fresh and frozen/thawed islets by determining the minimum number required to consistently reverse diabetes in mice. Defined numbers of islets, isolated from Balb/c (H-2^d) and CBA/J (H-2^k) mice, were transplanted into streptozotocin-induced diabetic Balb/c mice. Frozen/thawed grafts were cooled slowly to −40°C, stored at −196°C, and thawed rapidly. At 100 days after transplantation, isografts were recovered for measurement of insulin content. Mean (±SD) recovery of cryopreserved islets after thawing was 80 ± 3% (range 67–89%). For both fresh and frozen/thawed isografts and allografts, 200 islets were required to establish normoglycemia. The degree of metabolic function provided by equivalent quantities of fresh and frozen/thawed grafts was similar; and all normoglycemic isograft recipients remained so until graft nephrectomy. The insulin content of fresh and frozen/thawed isografts containing 200 and 300 islets were 151 ± 25 and 126 ± 8 mU and 259 ±36 and 278 ± 20 mU, respectively. Among allograft recipients, median survival ranged from 15 to 20 days, and was not influenced by cryopreservation or graft size. The results of this study demonstrate a high rate of recovery of viable islets following cryopreservation. The function of equivalent quantities of fresh and cryopreserved islet isografts and allografts in nonimmunosuppressed recipients is similar.     

Studies of the isolation, viability, and preservation of purified islets after surgical pancreatectomy in large pigs

Abstract: Previous studies have shown separation of mass quantities of islets from slaughterhouse pig pancreases. In these studies, we examined the isolation, viability, and preservation of pig islets obtained by surgical pancreatectomy. Pigs aged 6 to 30 months weighing 100 to 200 kg were subjected to laparotomy under general anesthesia. The splenic lobe of pancreas was mobilized without warm ischemia. Islets were immediately isolated by collagenase perfusion through the duct, automated dissociation, and Ficoll purification. Yields of islets (150 μm size) were 8500 to 9300/g for two different collagenases before purification. Purification yielded 90% pure islets, but yields decreased to 400 to 600/g. Perifusate insulin release was biphasic after glucose/theophylline with 3 to 5-fold stimulation. Following culture/cryopreservation marked islet losses occurred but viability was preserved. Quantities of 1,500 islet equivalents resulted in euglycemia in nude mice. These data show that mass quantities of viable islets can be isolated after pancreatectomy, but there is marked islet loss during purification and subsequent preservation due to inherent islet fragility.     

Neonatal pig pancreata as a source of insulin-producing tissue for xenotransplantation

Abstract: Islet transplantation has been proven as a viable option for treating type 1 diabetics; however, widespread clinical application of this technique will necessitate an alternative source of insulin-producing tissue. Porcine pancreata may be a potential source of islets, but adult porcine islets are difficult to isolate, are fragile, and have a tendency to fall apart during culture. In this study, we investigated the feasibility of preparing functionally viable islet cells in large quantities from the neonatal pig pancreas. Following collagenase digestion and 7 days of tissue culture, a mean of 48,000 neonatal islet cell (NIC) aggregates were recovered per pancreas. These NICs were responsive to glucose in vitro and were capable of correcting hyperglycemia in alloxan-induced diabetic nude mice. These results indicate that the neonatal porcine pancreas can be used to produce large numbers of functionally viable islet cells.     

Comparison of methods used for the removal of dmso following cryopreservation and the development of an automated protocol

Current methods of islet isolation are limited, thus requiring islets to be pooled from multiple donors to provide sufficient islet mass to permit insulin independence following islet transplantation. Low temperature banking is one approach used to pool islet preparations. Recently, we developed a method for bulk cryopreservation of islets in a single freezer bag system that is less labor-intensive and more readily kept sterile. As a further improvement to this bulk cryopreservation protocol we examined islet survival following slow-step dilution or our standard sucrose dilution protocol. Known numbers of canine islets were cryopreserved in DMSO by slow cooling to −40°C, storing at -196°C, and rapid thawing. When islets were frozen and thawed in glass tubes the recovery of islets after 48 h of tissue culture was significantly higher when the DMSO was removed using either a slow step (71.7 ± 2.7%) or a modified slow step (75.7 ± 3.9%) protocol as compared with the standard sucrose dilution protocol (65.7 ± 3.0%) (p < 0.05, unpaired t-test). Insulin secretion in vitro and in vivo graft function was similar between the experimental groups. Similarly, when islets were frozen then thawed in freezer bags, islet recovery following 48 h postcryopreservation tissue culture at 37°C was 74.8 ± 2.4% for slow-step dilution compared with 66.2 ± 2.7% for the standard sucrose dilution group (p < 0.05, unpaired t-test). Islets thawed in the freezer bag using the modified slow-step dilution protocol showed equivalent functional viability during static incubation to nonfrozen controls. Bulk cryopreservation of isolated islets in single blood freezer bags is a practical alternative to cryopreservation in glass tubes. Development of an automated protocol for the slow step-wise removal of the cryoprotectant from islets in freezer bags will facilitate low temperature tissue banking of islets.     

Evaluation of a Purified Enzyme Blend for the Recovery and Function of Canine Pancreatic Islets

Recently developed technologies enabling the production of a reproducible, purified enzyme blend for optimal human pancreatic islet isolation has renewed interest in clinical islet transplantation. The canine model has been an ideal preclinical model for the development of islet transplantation protocols. As seen in other species, the application of crude collagenase for isolating canine islets resulted in highly variable islet yields, extensive islet fragmentation, and variable islet functionality. We compared the function of commercially available crude collagenases with that of Liberase™-CI purified enzyme blend for canine islet isolation. We also compared two manufacturing runs of Liberase-CI enzyme (lots 1 and 2) to demonstrate reproducibility of islet recovery and function. We report on the improved recovery and function of islets isolated using Liberase-CI enzyme. No difference in dog age, mean body weight, or pancreas weight were observed between the experimental groups. We observed a significantly higher postpurification recovery of islet equivalent number (IE) from pancreases processed using two lots of Liberase-CI enzyme (189 ± 20 × 103 IE, n = 4) and lot 2 (234 ± 39 × 10³ IE, n = 7) than that obtained from pancreases processed with Sigma Type V (116.8 ± 27 × 10³ IE, n = 5), Serva collagenase (49 ± 11.6 × 10³ IE, n = 5, p < 0.05) or Boehringer–Mannheim (BM) Type P collagenase (85.4 ± 25 × 10³ IE, n = 5, p < 0.05, ANOVA). No significant differences were observed in islet yield recovery from pancreases processed using the two production lots of Liberase-CI enzyme. Islet survival after 48 h in culture at 37°C was significantly higher from islets isolated using Liberase-CI enzyme (88 ± 3.7% survival) when compared to Sigma Type V (81.8 ± 3.3%), Serva (71.7 ± 2.8%), and BM Type P (77 ± 7.2%) (p < 0.05). Islet functional testing in vitro demonstrated islets isolated using crude collagenase had an increased insulin basal release and a reduced insulin stimulated response when compared with islets isolated using the two lots of Liberase-CI enzyme. The calculated stimulation index was 7.8 ± 1.7, 3.1 ± 0.6, and 4.8 ± 1.1 for Sigma Type V, Serva, and BM Type P isolated islets, respectively, compared to 15.7 ± 1.6 and 16.2 ± 1.9 for islets isolated with Liberase-CI enzyme production lots 1 and 2, respectively (p < 0.05). This evaluation demonstrates that a purified enzyme blend can significantly improve islet recovery and function. It also demonstrates the manufacturing reproducibility of Liberase-CI enzyme lots resulting in the isolation of canine islets with the same degree of efficacy. A blend of purified enzymes, specifically formulated for canine islet isolation, can consistently yield large numbers of islets that survive longer in culture and demonstrate an improved insulin response in vitro.     

A prospective comparison of discontinuous EuroFicoll and EuroDextran gradients for islet purification

Density gradient separation of islets from exocrine tissue is usually performed with Ficoll. However, this reagent adds significantly to the cost of the isolation. The aim of this study was to evaluate the performance of Dextran as a potential low-cost substitute for Ficoll and to evaluate the effects of cold storage of the pancreatic digest prior to purification. Pancreases were procured from mongrel dogs, loaded with collagenase and mechanically dissociated. Washed pancreatic digest was collected and divided into two fractions that were purified using discontinuous gradients on the Cobe 2991 processor using identically prepared EuroFicoll (EF) or EuroDextran (ED) gradients. Alternate groups were suspended in EC and stored on ice, while the other fraction were resuspended in the 1.108-g/mL gradient layer (either EF or ED) and loaded into the COBE. This tissue layer was overlaid with layers of densities 1.096 and 1.037 g/mL and a HBSS cap, and centrifuged for 5 min at 800 × g. Purified islets were collected from the interface between the 1.037 and 1.096 layers and islet recovery, purity, and function were assessed. From a series of eight isolations, 72.9 ± 8.2% (mean ± SEM) of the islets were recovered from the EF purified gradients compared with 62.6 ± 8.3% from ED gradients (p = NS, paired t-test). Gradients of ED that were run following hypothermic storage of the digest in cold EC solution (stored ED) had reduced islet recovery when compared with islet recovery from gradients prepared in EF(stored EF) (51.6 ± 9.6% for ED stored vs. 72.9 ± 11.9 for EF stored, p < 0.05). Islet recovery from EF gradients was equivalent between the stored and nonstored groups. The purity of preparations from the stored ED gradients was also reduced (71.3 ± 4.3%) when compared with islets that were immediately purified after dissociation (82.5 ± 4.8%, p < 0.05). Static glucose stimulation assay showed equivalence between the islets from ED and EF gradients. The stimulation index (SI) was 9.3 ± 0.9 for EF islets compared with 7.9 ± 1.4 for ED islets for digest purified immediately. However, if the digest was hypothermically stored in EC solution, a decrease in functional viability was observed in both the EF and the ED groups (7.7 ± 1.4 and 5.9 ± 0.8, respectively). Out of five alloxan-induced diabetic nude mice transplanted under the kidney capsule with 2000 islets isolated from the nonstored groups, three remained euglycemic >50 days posttransplant with either EF or ED islets. These experiments demonstrate effective recovery of equivalent numbers of canine islets using discontinuous gradients of ED or EF immediately following enzymatic digestion. However, following storage of the digest in cold EC solution results in a reduction in both islet recovery and function when gradients of ED are utilized.     

The use of pancreas biopsy scoring provides reliable porcine islet yields while encapsulation permits the determination of microbiological safety

For clinical xenogenic islet transplantation to be successful, several requirements must be met. Among them is a sizeable and reliable source of fully functional and microbiologically safe islets. The inherent variability among porcine pancreases, with respect to islet yield, prompted us to develop a Biopsy Score technique to determine the suitability of each pancreas for islet isolation processing. The Biopsy Score consists of an assessment of five variables: warm ischemia time, pancreas color, fat content, islet size, and islet demarcation, each of which is assigned a value of -1 or +1, depending on whether or not the established criteria is met. For determination of islet size and demarcation, fresh biopsies of porcine pancreases are stained with dithizone (DTZ) solution and examined under a dissecting microscope. Based on the scoring of such biopsies in pancreases from 26-56-month-old sows, we report here that the presence of large (>100 microm diameter), well-demarcated islets in the pancreas biopsy is a reliable predictor of isolation success. Encapsulation of the isolated porcine islets within the inner layer of a 1.5% agarose and an outer layer of 5.0% agarose macrobead, containing 500 equivalent islet number (EIN), provides for extended in vitro functional viability (>6 months of insulin production in response to glucose), as well as for comprehensive microbiological testing and at least partial isolation of the xenogeneic islets from the host immune system. All microbiological testing to date has been negative, except for the presence of porcine endogenous retrovirus (PERV). Taken together, we believe that the Biopsy Score enhancement of our islet isolation technique and our agarose-agarose macroencapsulation methodology bring us significantly closer to realizing clinical porcine islet xenotransplantation for the treatment of insulin-dependent diabetic patients.     

Automated large-scale isolation, in vitro function and xenotransplantation of porcine islets of Langerhans

To evaluate the potential of utilizing porcine islet tissue as an alternative to human islet tissue for transplantation, we developed a method for the isolation of large amounts of highly purified porcine islets, and assessed the in vitro and in vivo function of the isolated islets after 1, 4, and 7 days of culture. The pancreatic duct of the splenic lobe was cannulated and distended by injection of Hanks' balanced salt solution containing 1.5 mg/ml collagenase. The pancreas was then processed by a modification of the automated digestion-filtration method developed in this laboratory, and with purification accomplished by Euro-Ficoll gradients (dialyzed Ficoll in Eurocollins solution), consisting of two layers of 1.108 and 1.091 g/cm3 density, topped with a layer of HBSS. The postpurification yield was 5203 +/- 645 (mean +/- SEM) islets per gram of pancreas with a number of islet equivalents (IE) per gram pancreas (islet equivalence: 150-microns-sized islets) of 3551 +/- 305, and a volume of 6.27 +/- 1.7 mm3 islet tissue per gram of pancreas. The islet purity exceeded 90%. Overnight-cultured, perifused porcine islets released 53.1 +/- 8.2 pM insulin/200 IE at 3.3 mM glucose, and 114.9 +/- 25.4 pM insulin/200 IE at 16.7 mM glucose (P less than 0.001 vs. basal output). When theophylline was added, insulin secretion increased to 264.2 +/- 63.2 pM/200 IE (P less than 0.001 vs. basal secretion and P less than 0.005 vs. secretion at 16.7 mM glucose). After 4 days of culture, the islets still responded to secretagogues. The functional integrity of the isolated islets was confirmed by reversal of diabetes in aL3T4 antibody-treated C57B/B6 diabetic mice: normoglycemia was promptly restored by transplanting 1000 overnight- or 7-day-cultured (24 degrees C) islets under the kidney capsule. These results suggest that continued improvements of porcine islet isolation and culture could permit the use of porcine islets in immunoalteration and immunoisolation studies that may lead to eventual human transplantation.     

Comparison of methods for isolating primary hepatocytes from mini pigs

Successful porcine hepatocyte isolation is crucial for the development of bioartificial liver devices and hepatocyte transplantation. Serva collagenase NB grades are formulated collagenases that are suitable for various tissue isolation applications. N‐acetylcysteine (NAC) can improve the viability of human hepatocytes. The aim of this study was to compare the effectiveness of two collagenases and effect of NAC on hepatocyte isolation from porcine liver tissue. Porcine hepatocytes were isolated using the perfusion method from Bama mini pigs assigned to the Serva NB 4 group (n=6), the Serva NB 8 group (n=6), or the NB 8+NAC group (n=6). Viability and yield were defined as fresh hepatocytes and their spheroids formation after 24‐hour rocker culture in serum‐free medium. Metabolic function was assessed by gene expression, albumin, and urea synthesis. All procedures resulted in successful hepatocyte isolation. Cells from the NB 8+NAC group had (97.8±1.9)% viability, which was higher than the NB 8 group with (94.4±2.4)% and the NB 4 group with (94.5±3.2)% (P<.001). The final cell yield reached (11.8±1.0)×10⁹ cells in the NB 8+NAC group, compared to (9.5±2.1)×10⁹ cells in the NB 8 group (P<.01) and (9.1±1.1) ×10⁹ cells in the NB 4 group (P<.001). The secretion of albumin was superior in the NB 8+NAC group at a concentration of (425.8±35.3) ng/mL compared to the NB 8 group (339.1±32.6) ng/mL (P <.001) and NB 4 group (293.6±43.3) ng/mL (P <.01). The injury of hepatocytes also decreased in the NB 8+NAC group (P<.01). The data are presented as means ± SD. Formulated collagenase Serva NB 8 and NAC could improve the porcine hepatocyte isolation, resulting in higher yields of viable cells.     

Maintenance of glucose-sensitive insulin secretion of cryopreserved human islets with University of Wisconsin solution and ascorbic acid-2 glucoside

Normal human islet cells are an ideal source for pancreas-targeted cell therapies, but the availability of human donor pancreata for islet isolation is severely limited. To effectively utilize such scarce donor organs for cell therapies, it is crucial to develop an excellent isolation, effective cryopreservation, and efficient gene transfer techniques for the transportation of isolated cells. In the present study, we investigate the effect of University of Wisconsin (UW) solution and ascorbic acid-2 glucoside (AA2G) on the cryopreservation of human islets. We also evaluate the gene transfer efficiency of a lentiviral vector expressing the E. coli LacZ gene, Lt-NLS/LacZ, in human islets. Human islets were isolated with a standard digestion method at the University of Alberta. Isolated islets were transported to Japan for 40 h and then subjected to cryopreservation experiments. The following preservation solutions were tested: UW solution with 100 micro g/mL of AA2G, UW solution, 100% fetal bovine serum (FBS), and CMRL supplemented with 10% FBS. Following three months of cryopreservation, the islets were thawed and analyzed for viability, glucose-sensitive insulin secretion, proinsulin gene expression profile, and in vivo engraftment. The islets were also subjected to monolayer formation with 804G-cell-line-derived extracellular matrix (ECM), followed by Lt-NLS/LacZ transduction. The viability, morphology, glucose-sensitive insulin secretion, proinsulin gene expression, and monolayer formation efficiency of the thawed cryopreserved islets are significantly better maintained by the use of UW solution. When AA2G (100 microg/mL) is combined with UW, such parameters are further improved. The adequate engraftment of UW + AA2G-cryopreserved human islets is achieved in the liver of nude mice. Efficient Lt-NLS/LacZ transduction is identified in monolayered islets cryopreserved with UW solution with AA2G. The present work demonstrates that the combination of UW solution with AA2G (100 microg/mL) would be a useful cryopreservation means for human islets. Human islets monolayer-cultured with 804G-derived ECM are efficiently transduced with a lentiviral vector Lt-NLS/LacZ.     

Neonatal porcine pancreatic cell clusters as a potential source for transplantation in humans: characterization of proliferation,apoptosis, xenoantigen expression and gene delivery with recombinant AAV

Abstract: Neonatal porcine islets are characterized by reproducible isolation success and high yields, sizable advantages over adult islets. In this work we have analyzed selected phenotypic and functional characteristics of porcine neonatal islets relevant to their possible use for transplant in humans. We show that porcine islet cells proliferate in culture, and synthesize and store islet-specific hormones. Proliferating beta cells can be easily identified. Implant of cultured neonatal islets in immunodeficient rodents results in the reversal of diabetes, albeit with delay. We also show that measurable apoptosis occurs in cultured neonatal porcine islets. Further, antigens recognized by human natural antibodies are expressed in a dynamic fashion over the culture period analyzed and are not limited to the alpha-Gal epitope. Lastly, we demonstrate that a recombinant Adeno-Associated virus can be used to efficiently deliver a reporter gene in porcine islets. This characterization might be helpful in the definition of the potential use of neonatal porcine islets for human transplantation.     

The morphology of islets within the porcine donor pancreas determines the isolation result: successful isolation of pancreatic islets can now be achieved from young market pigs

Clinical islet allotransplantation has become an increasingly efficient "routine" therapy in recent years. Shortage of human donor organs leads to porcine pancreatic islets as a potential source for islet xenotransplantation. Yet it is still very difficult to isolate sufficient numbers of intact porcine islets, particularly from young market pigs. In the following study islets were successfully isolated from retired breeders [4806 +/- 720 islet equivalents per gram organ (IEQ/g); n = 25; 2-3 years old; RB] and also from young hybrid pigs [2868 +/- 260 IEQ/g; n = 65; 4-6 months old; HY] using LiberasePI and a modified version of Ricordi's digestion-filtration technique. As expected, isolations from RB showed significantly better results (p < 0.002). A retrospective histological analysis of almost all donor pancreases showed that the majority of organs from RB (80%) contained mainly large islets (diameter > 200 microm), in contrast to only 35% of all pancreases from HY. Remarkably, the islet size in situ, regardless whether detected in RB or HY, strongly determined the isolation result. A donor organ with predominantly large islets resulted in significantly higher numbers of IEQs compared with a donor organ with predominantly small islets [RB(Large Islets): 5680 +/- 3,318 IEQ/g (n= 20); RB(Small Islets): 1353 +/- 427 IEQ/g (n = 5); p < 0.02]. In addition, isolation results were strongly influenced by the quality of the LiberasePI batch, and therefore single batch testing is invariably required. Purification was performed using Ficoll or OptiPrep density gradient centrifugation manually or in the COBE cell processor. Although islet purity was highest when OptiPrep was used, final islet yields did not differ between the different purification methods. Our study demonstrates that islet size in situ is an extremely critical parameter for highly successful islet isolation; consequently, we are now performing a morphological screening of each donor organ prior to the isolation process. Under these conditions highly successful isolations can reliably be performed even from young market pigs.     

Natural history of multiple intrahepatic canine islet allografts during and following administration of cyclosporine

Cyclosporine (CsA) prevented acute rejection of intrahepatic canine islet allografts (IHIA) in 5/5 pancreatectomized dogs. Normal fasting blood glucose levels were sustained in these dogs for 210 +/- 78 days (mean +/- SEM) following withdrawal of CsA. We tested whether combining islets from more than one pancreas would improve function and prolong islet allograft survival during and following administration of CsA. Areas under the glucose disappearance (GDA) and C-peptide response (CPA) curves following i.v. glucose (0.5 g/kg), 1 month posttransplant were not significantly different using islets from 1 or 2 pancreases, whereas GDA and CPA approached normal if islet yields from 3 or more pancreases were combined. Mean islet allograft survival following interruption of CsA decreased with an increase in the number of donor pancreases (one: 210 +/- 78 days, vs. two: 113 +/- 23 days, vs. greater than 2: 57 +/- 5 days). These studies demonstrate that: (1) IHIA uniformly resulted in fasting euglycemia in 36 of 38 diabetic dogs treated with CsA; (2) normal i.v. glucose metabolism required the combined islet yield of 3 or more donor pancreases, suggesting that a substantial number of intrahepatic islet cells are functionally lost despite effective CsA-induced immunosuppression; (3) use of multiple donors to accumulate an increased mass of islets may immunologically compromise allograft survival following discontinuation of CsA (these experiments, however, do not exclude a direct relationship between the duration of CsA therapy and the duration of immune unresponsiveness following interruption of CsA in multidonor islet allografts as an independent variable); and (4) unmodified islets obtained from multiple donors seem to require continuous immunosuppression to prevent rejection.     

Effects of simulated microgravity on the morphology and function of neonatal porcine cell clusters cultured with and without Sertoli cells

Human islet allografts are well known to induce full and sustained remission of hyperglycemia, with complete normalization of key metabolic parameters. Nevertheless, acquiring human islets, even from cadaveric human donor pancreases, remains a significant impediment to successful transplantation therapy for diabetes. To overcome this difficulty, neonatal porcine cell clusters (NPCCs) have been considered for human islet substitutes because they are easily obtained by collagenase digestion of the neonatal piglet pancreas. Currently, the major hurdle in using NPCCs for xenograft is the delay (time lag) in achieving the posttransplant normalization of blood glucose levels in animal diabetic recipients. The present work is the first attempt to evaluate whether incubation of NPCCs in simulated microgravity, in the presence or absence of Sertoli cells (SC), may reduce the maturation time lag of beta-cells by differentiation acceleration in vitro, thereby expediting production, viability, and acquisition of functional competence of pretransplantation beta-cell-enriched islets. Following a 3-day incubation period, NPCCs maintained in conventional culture, NPCCs incubated in simulated microgravity in the HARV biochamber, and NPCCs plus co-incubated SC in simulated microgravity were examined for viability, morphology, and insulin secretion. Results show that NPCCs grown alone in the HARV biochamber are superior in quality, both in terms of viability and functional competence, when compared to other culture pretreatment protocols. This finding strongly suggests that NPCC pretreatment in simulated microgravity may enhance the transplantation success of NPCCs in the diabetic recipient.