Human islet separation utilizing a closed automated purification system.

A central step within the human islet isolation process is the separation of islets from contaminating exocrine tissue utilizing linear, continuous density gradients manufactured by means of manually controlled standard gradient makers (SGM). The present study was performed to develop a closed, automated purification system (APS) that customizes density gradient profiles aiming to standardize and optimize human islet purification. Digested human pancreata were pooled, split evenly, and incubated in UW solution according to our standard protocol (n = 11). Continuous density gradient centrifugation was performed in parallel in two refrigerated COBE 2991 cell separators loaded with light (1.076 g/ml) and heavy (1.097 g/ml) Ficoll utilizing either an SGM or two computer-controlled pumps connected to Ficoll-containing bags. Quality control included islet equivalent (IE) yield, purity, in vitro function, and islet cytokine expression. Gradient profiles demonstrated that the APS readily customizes linear and nonlinear gradients. In comparison to the SGM, the APS recovered a higher percentage of the expected volume of continuous gradients (90.0 +/- 1.1% vs. 98.2 +/- 2.0%, p < 0.05). Islet yield (120,468 +/- 15,970 vs. 114,570 +/- 15,313 IE, NS) and purity (51.7 +/- 4.8% vs. 54.4 +/- 4.9%, NS) were nearly identical utilizing the SGM or APS. Decreased MCP-1, IL-6, and IL-8 expression indicated that APS-purified islets were possibly exposed to less proinflammatory stress. Compared to standard procedures, similar success and gentle continuous density gradient separation of human islets is feasible utilizing the APS. The APS facilitates the standardization of this complex procedure according to cGMP standards.

Degraded collagenase deteriorates islet viability.

OBJECTIVE: The utilization of purified enzyme blends consisting of collagenase class I (CI) and II (CII) and neutral protease is an essential step for clinical islet isolation. Previous studies suggested that the use of enzyme lots containing degraded CI reduced islet release from human pancreata. The present study sought to assess the effect of degraded collagenase on islet function in vitro and posttransplantation. MATERIALS AND METHODS: Crude collagenase was chromatographically separated into CI, CII, and a mixture of degraded CI and CII isomers. Subsequently, classes were recombined to obtain a CII/CI ratio of 0.5. Rat islets were isolated utilizing neutral protease and 20 units of recombined collagenase containing either intact (Ci) or degraded isomers (Cd). RESULTS: Digestion time was reduced utilizing Cd (P < .001). The highest islet yield and lowest islet fragmentation were obtained with Ci (P < .01). Utilization of Cd corresponded to a reduction in viability and in vitro function (NS). Islet transplantation reversed hyperglycemia in diabetic nude mice, but revealed an absence of weight gain in recipients receiving islets isolated using Cd (P < .01). CONCLUSION: This study suggested that islet function posttransplantation is affected by degraded collagenase isomers. This finding has to be considered for the purification process of collagenase.

New class of oxygen carriers improves islet isolation from long-term stored rat pancreata.

OBJECTIVE: Pancreas shipment is frequently associated with prolonged ischemia deteriorating islet graft function. The strategy to prevent ischemic damage utilizing perfluorodecalin (PFD) for human pancreas oxygenation does not seem to improve isolation outcome. The present study investigated the efficiency of perfluorohexyloctane (F6H8), a hyperoxygen carrier characterized by low specific density (1.33 g/cm3) and lipophilic qualities, to facilitate islet isolation from long-term stored rat pancreata. MATERIALS AND METHODS: Prior to islet isolation, pancreata were intraductally flushed in situ with Kyoto solution (KS) and stored for 24 hours in KS, oxygenated PFD, or F6H8. RESULTS: Islet isolation performed after 24-hour storage in KS failed completely. The intrapancreatic pO2 in PFD- and F6H8-incubated pancreata was almost the same. In correspondence, the ATP content and viability of isolated islets were similar as well. In contrast, islet yield and in vitro function were significantly reduced after storage in PFD compared with F6H8. CONCLUSION: This study suggested that islet isolation performed after long-term pancreas preservation can be significantly improved utilizing semifluorinated alkanes as oxygen carriers.

Metabolic effects of successful intraportal islet transplantation in insulin-dependent diabetes mellitus.

The intraportal injection of human pancreatic islets has been indicated as a possible alternative to the pancreas transplant in insulin-dependent diabetic patients. Aim of the present work was to study the effect of intraportal injection of purified human islets on: (a) the basal hepatic glucose production; (b) the whole body glucose homeostasis and insulin action; and (c) the regulation of insulin secretion in insulin-dependent diabetes mellitus patients bearing a kidney transplant. 15 recipients of purified islets from cadaver donors (intraportal injection) were studied by means of the infusion of labeled glucose to quantify the hepatic glucose production. Islet transplanted patients were subdivided in two groups based on graft function and underwent: (a) a 120-min euglycemic insulin infusion (1 mU/kg/min) to assess insulin action; (b) a 120-min glucose infusion (+75 mg/di) to study the pattern of insulin secretion. Seven patients with chronic uveitis on the same immunosuppressive therapy as grafted patients, twelve healthy volunteers, and seven insulin-dependent diabetic patients with combined pancreas and kidney transplantation were also studied as control groups. Islet transplanted patients have: (a) a higher basal hepatic glucose production (HGP: 5.1 +/- 1.4 mg/kg/ min; P < 0.05 with respect to all other groups) if without graft function, and a normal HGP (2.4 +/- 0.2 mg/kg/min) with a functioning graft; (b) a defective tissue glucose disposal (3.9 +/- 0.5 mg/kg/min in patients without islet function and 5.3 +/- 0.4 mg/kg/min in patients with islet function) with respect to normals (P < 0.01 for both comparisons); (c) a blunted first phase insulin peak and a similar second phase secretion with respect to controls. In conclusion, in spite of the persistence of an abnormal pattern of insulin secretion, successful intraportal islet graft normalizes the basal HGP and improves total tissue glucose disposal in insulin-dependent diabetes mellitus.

Effect of pretransplant preconditioning by whole body hyperthermia on islet graft survival.

Previous observations in heat-shocked pig islets revealed the ambivalent character of the stress response simultaneously inducing processes of protection and apoptosis. To clarify whether the proapoptotic character of the stress response is reduced in heat-exposed islets still embedded in their native environment, hyperthermia was performed in the present study either as whole body hyperthermia (WBH) prior to pancreas resection or as in vitro heat shock (HS) after isolation. HS (42 degrees C/45 min) was induced in donors 12 h before isolation (WBH, n = 32) or in freshly isolated islets prior to 12 h of culture at 37 degrees C (in vitro HS, n = 25). Islets continuously incubated at 37 degrees C served as controls (n = 34). Proinflammatory treatment was performed with H2O2, DETA-NO, or a combination of IL-1beta, TNF-alpha, and IFN-gamma. Quality assessment included islet yield, viability staining, static glucose incubation, and nude mouse transplantation. WBH was significantly less effective than in vitro HS to induce HSP70 overexpression and to increase islet resistance against inflammatory mediators. Although characterized by an unaltered Bax to Bcl-2 ratio, islets subjected to WBH partially failed to restore sustained normoglycemia in diabetic nude mice. The inflammatory response observed in the pancreas of WBH-treated rats was associated with significantly reduced viability that seems to have a higher predictive value for posttransplant outcome compared to islet in vitro function or mitochondrial activity. In contrast, in vitro HS significantly decreased transcript levels of Bcl-2, but did not affect posttransplant function compared to sham-treated islets. These findings suggest that WBH is primarily associated with increased necrosis as a secondary tissue type-specific effect of pancreas damage while in vitro HS mainly induces apoptosis.

Effect of Etanercept Concentration on Human Islet Integrity.

BACKGROUND: Etanercept is widely used as an antiinflammatory drug to improve engraftment after intraportal islet transplantation. In contrast to other immunosuppressive agents, very little is known about detrimental effects of etanercept on islets. The aim of this pilot study was to define the toxic range of etanercept. METHODS: Human islets isolated from 8 donors were cultured for 4-5 days at 37°C in culture medium supplemented with etanercept at concentrations from 2.5 to 40 µg/mL, corresponding to potential in vivo levels within the portal vein. After culture, islet equivalent (IEQ) yield, fragmentation index (islet number/IEQ), purity, viability, and stimulated insulin release (2 vs 20 mmol/L) were assessed and normalized to islets before culture. RESULTS: Yield (73 ± 8%) and viability (91 ± 4%) were highest with 5 µg/mL etanercept. Islet loss was evident when etanercept was ≥10 µg/mL (55 ± 7%; P < .05 vs control). Fragmentation (154 ± 34%; P < .05) was markedly increased and viability (81 ± 4%, P < .05) markedly decreased with etanercept >10 µg/mL. The accumulation of cell debris at concentrations ≥20 µg/mL resulted in a significant reduction of islet purity (84 ± 3%; P < .05). Etanercept did not interfere with stimulated insulin secretion at concentrations ≤10 µg/mL. The maximum stimulation index was noted at 2.5 µg/mL (1.8 ± 0.1). CONCLUSIONS: Etanercept is tolerated by isolated human islets at concentrations <10 µg/mL. Our data suggest that the tight range between benefit and toxicity should be considered for dosage and administration of etanercept.

Hypoxia-Induced Damage in Human Islets Is Reduced With the Use of Mesenchymal Stem Cell-Preconditioned Medium.

BACKGROUND: Mesenchymal stem cells (MSCs) are protective for islets when cotransplanted in a hypoxic environment. However, the risk of neoplasia is increased when MSCs are transplanted into immunosuppressed patients. This initial study aimed to investigate whether the production of protective factors from MSC can be stimulated by different culture conditions to benefit human islets cultured in hypoxia. METHODS: MSC were isolated from human adipose tissue and cultured for 2 days in supplemented Minimum Essential Media α (MEMα) and 21% (21%-MEMα) or 1% oxygen (1%-MEMα). Native MEMα served as control. After MSC harvesting, cell-depleted media were frozen at -20°C until use for human islet culture in 2% oxygen for 72-96 hours before islet characterization. Data were normalized to control islets cultured in native MEMα and 2% oxygen (mean ± SEM). RESULTS: After culture in 21%- or 1%-MEMα, islet recovery increased to 117 ± 12% (NS) and 138 ± 12% (P < .05), respectively. Viability did not change after culture in native MEMα (59 ± 2%), 21%-MEMα (59 ± 3%), or 1%-MEMα (61 ± 3%). Compared with control samples, the glucose stimulation index was increased after culture in 21%-MEMα (P < .05) or 1%-MEMα (P < .05). Overall survival was higher in 1%-MEMα (143 ± 14%) than in 21%-MEMα (119 ± 14%; NS) or native MEMα (P < .05). CONCLUSIONS: This study demonstrates that MSC-preconditioned MEMα increases survival and in vitro function of hypoxic human islets. These findings indicate that hypoxic MSCs seem to produce factors that improve survival of islets suffering from hypoxia.

Adiponectin is functionally active in human islets but does not affect insulin secretory function or beta-cell lipoapoptosis.

CONTEXT: The adipokine adiponectin has insulin-sensitizing, antiatherogenic, and antiinflammatory properties. Mouse and human adiponectin receptor-1 and -2 have been cloned, both of which are expressed in various tissues and mediate effects of globular and full-length adiponectin. Whether adiponectin affects insulin secretion and beta-cell apoptosis and whether plasma adiponectin is associated with beta-cell function in humans is under investigation. DESIGN AND METHODS: In human islets from multiorgan donors, we investigated expression of adiponectin receptor-1 and -2. Furthermore, glucose-stimulated insulin secretion was determined by RIA. In addition, we investigated fatty acid-induced beta-cell apoptosis by terminal dUTP nick end labeling and flow-cytometric cell cycle analysis (sub-G1 formation). In humans in vivo, insulin secretory function was measured during hyperglycemic clamps in 65 normal glucose-tolerant subjects. We determined first and second phase of glucose-stimulated, glucagon-like peptide-1-stimulated, and arginine-stimulated insulin secretion. RESULTS: Adiponectin receptor-1 and -2 are expressed in human islets at the mRNA and protein level. Moreover, full-length adiponectin induces phosphorylation of acetyl coenzyme A carboxylase. However, adiponectin did not affect basal or glucose-stimulated insulin secretion or basal or fatty acid-induced beta-cell apoptosis. In vivo, fasting plasma adiponectin concentrations were not associated with glucose-stimulated first- and second-phase insulin secretion or with glucagon-like peptide-1- or arginine-stimulated insulin secretion (all P > 0.42). CONCLUSIONS: These data support a regulatory role of adiponectin in human islets; however, adiponectin does not seem to affect insulin secretion or basal/fatty acid-induced beta-cell apoptosis in humans.

Incompatibility between human blood and isolated islets of Langerhans: a finding with implications for clinical intraportal islet transplantation?

The remarkable difference in success rates between clinical pancreas transplantation and islet transplantation is poorly understood. Despite the same histocompatibility barrier and similar immunosuppressive treatments in both transplantation procedures, human intraportal islet transplantation has a much inferior success rate than does vascularized pancreas transplantation. Thus far, little attention has been directed to the possibility that islets transplanted into the blood stream may elicit an injurious incompatibility reaction. We have tested this hypothesis in vitro with human islets and in vivo with porcine islets. Human islets were exposed to nonanticoagulated human ABO-compatible blood in surface-heparinized polyvinyl chloride tubing loops. Heparin and/or the soluble complement receptor 1 (sCR1) TP10 were tested as additives. Adult porcine islets were transplanted intraportally into pigs, and the liver was recovered after 60 min for immunohistochemical staining. Human islets induced a rapid consumption and activation of platelets. Neutrophils and monocytes were also consumed, and the coagulation and complement systems were activated. Upon histological examination, islets were found to be embedded in clots and infiltrated with CD11+ leukocytes. Furthermore, the cellular morphology was disrupted. When heparin and sCR1 were added to the blood, these events were avoided. Porcine islets retrieved in liver biopsies after intraportal islet allotransplantation showed a morphology similar to that of human islets perifused in vitro. Thus, exposure of isolated islets of Langerhans to allogenic blood resulted in significant damage to the islets, a finding that could explain the unsatisfactory clinical results obtained with intraportal islet transplantation. Because administration of heparin in combination with a soluble complement receptor abrogated these events, such treatment would presumably improve the outcome of clinical islet transplantation by reducing both initial islet loss and subsequent specific immune responses.

Metabolic effects of restoring partial beta-cell function after islet allotransplantation in type 1 diabetic patients.

Successful intraportal islet transplantation normalizes glucose metabolism in diabetic humans. To date, full function is not routinely achieved after islet transplantation in humans, with most grafts being characterized by only partial function. Moreover, the duration of full function is variable and cannot be sufficiently predicted with available methods. In contrast, most grafts retain partial function for a long time. We hypothesized that partial function can restore normal protein and lipid metabolism in diabetic individuals. We studied 45 diabetic patients after islet transplantation. Labeled glucose and leucine were infused to assess whole-body glucose and protein turnover in 1) 6 type 1 diabetic patients with full function after intraportal islet transplantation (FF group; C-peptide > 0.6 nmol/l; daily insulin dosage 0.03 +/- 0.02 U x kg(-1) body wt x day(-1); fasting plasma glucose < 7.7 mmol/l; HbA1c < or = 6.5%), 2) 17 patients with partial function (PF group; C-peptide > 0.16 nmol/l; insulin dosage < 0.4 U x kg(-1) body wt x day(-1)), 3) 9 patients with no function (NF group; C-peptide < 0.16 nmol/l; insulin dosage > 0.4 U x kg(-1) body wt x day(-1)), and 4) 6 patients with chronic uveitis as control subjects (CU group). Hepatic albumin synthesis was assessed in an additional five PF and five healthy volunteers by means of a primed-continuous infusion of [3,3,3-2H3]leucine. The insulin requirement was 97% lower than pretransplant levels for the FF group and 57% lower than pretransplant levels for the PF group. In the basal state, the PF group had a plasma glucose concentration slightly higher than that of the FF (P = 0.249) and CU groups (P = 0.08), but was improved with respect to the NF group (P < 0.01). Plasma leucine (101.1 +/- 5.9 micromol/l) and branched-chain amino acids (337.6 +/- 16.6 micromol/l) were similar in the PF, FF, and CU groups, and significantly lower than in the NF group (P < 0.01). During insulin infusion, the metabolic clearance rate of glucose was defective in the NF group versus in the other groups (P < 0.01). Both the basal and insulin-stimulated proteolytic and proteosynthetic rates were comparable in the PF, FF, and CU groups, but significantly higher in the NF group (P = 0.05). In addition, the PF group had a normal hepatic albumin synthesis. Plasma free fatty acid concentrations in the PF and FF groups were similar to those of the CU group, but the NF group showed a reduced insulin-dependent suppression during the clamp. We concluded that the restoration of approximately 60% of endogenous insulin secretion is capable of normalizing the alterations of protein and lipid metabolism in type 1 diabetic kidney recipients, notwithstanding chronic immunosuppressive therapy. The results of the present study indicate that "success" of islet transplantation may be best defined by a number of metabolic criteria, not just glucose concentration/metabolism alone.

Glucose sensitivity of porcine and human islets in vitro.

Preliminary experiments about the suitability of different commonly used culture media in our laboratory indicated, that prolonged exposure to high glucose concentrations during low temperature culture (LTC) impairs the viability of long term cultured human islets. As a consequence of the heterogeneity of tested media the present study was aimed to evaluate the influence of different glucose concentrations on survival, viability and in-vitro function of cultured human islets in order to optimize islet survival until transplantation and to compare species dependent differences in glucose sensitivity. Quantified aliquots of freshly isolated (digestion-filtration, ficoll gradient purification) islets from consecutively processed human (n=6) and porcine (n=11) pancreata were subjected to different glucose concentrations (human islets: 500, 750, 1000 and 2000 mg/l; porcine islets: 1000 and 2000 mg/l) in CMRL (22 degrees C) for 8-10 days. After LTC survival, viability and glucose-stimulated insulin release of incubated tissue was assessed. A reduction of glucose concentration promotes survival and viability of human islets but impairs in vitro function at the same time, presumably due to a reduced glucose oxidation as expressed by the significantly reduced stimulation index. In contrast to these findings in the human, elevated glucose concentration in porcine islet culture increases survival but reduces the glucose-stimulated insulin release and the viability of cultured islets. The contradiction of the results in regard to islet survival related to islet viability are still unclear in the pig and needs further evaluation.

Large variability of the intracellular ATP content of human islets isolated from different donors.

Observations in experimental heart, liver, kidney and pancreas transplantation indicated that graft function and survival correlates significantly with ATP content of transplanted tissue. The ATP content of cells can be reduced by several factors i.e. the nutritional donor status, storage technique, warm ischemia and cold ischemia time. This study investigates the intracellular ATP content of isolated human islets for the first time. Quantified samples of freshly isolated (digestion-filtration, continuous ficoll gradient purification) and cultured (22 degrees C, CMRL+10% FCS) islet equivalents (IEQ) of consecutively processed human pancreata from multiorgan donors (UW vascular flush) were shock frozen in liquid nitrogen and stored at -196 degrees C until rapid thawing, sonification and subsequent luminometric determination of ATP (Luciferin-Luciferase-reaction) and assessment of islet protein (IP). The ATP content was analysed for freshly isolated and subsequently 5+/-1 days cultured islets (n=10). The ATP content of freshly isolated human islets was 130.4+/-53.4 pg/microg IP (mean+/-SEM) corresponding to 20.7+/-6.3 pg/IEQ. After culture ATP content increased to 265.5+/-113.3 pg/microg IP (204.2+/-41.5%) corresponding to 43.7+/-15.3 pg/IEQ (216.1+/-34.9%; p<0.05). The coefficient of variation was 129.5%, 96.5% (fresh) and 135.0%, 111.0% (cultured) for ATP/microg IP and ATP/IEQ, respectively. The present data show that: (1) the ATP content of freshly isolated human islets varies enormously; (2) intraislet ATP levels increase significantly during 22 degrees C culture suggesting that the capacity to produce ATP is maintained despite hypothermic environment. More data are necessary to clarify the relevance of intraislet ATP content for graft function and survival after islet transplantation.

Evidence for a significant correlation of donor pancreas morphology and the yield of isolated purified human islets.

In clinical islet transplantation to patients with type 1 diabetes mellitus, the number of isolated and purified islet has been identified as a key determinant for functional success of the islet graft. With improved isolation methods based on the original procedure published by Ricordi et al. yield and function of isolated islets were considerably enhanced. However, there is still a large variance in the number, purity, viability and secretory capacity of islets isolated from brain-dead human donor pancreata, significantly hampering utilization of human islet preparations derived from a single donor for one diabetic recipient. The reasons for the limited success in islet isolation and purification have not been clarified in detail yet. Recent studies have indicated, that donor preconditions, and a number of technical factors during organ procurement and the islet isolation process itself are critical to successful islet isolation. This study aimed at identifying distinct morphological and histopathological characteristics of the donor pancreas as determinants for the outcome of human islet isolation and purification.

Cytokine mRNA expression in peripheral blood cells of immunosuppressed human islet transplant recipients.

The macrophage derived cytokines interleukin-beta (IL-1beta), and tumor necrosis factor alpha (TNFalpha), and the T-cell derived cytokine interferon gamma (IFNgamma) have been implicated to play an important role in early attack on islet cells during human islet transplantation (ITx). Therefore, the aim of this study was to investigate the influence of the current immunosuppressive induction therapy in clinical islet transplantation on mRNA expression of these cytokines in blood cells, compared to lipopolysaccharide (LPS) induced cytokine release in vitro and to plasma levels. The cytokine release correlated to lymphocyte counts and significantly decreased after ATG, and partially recovered 2 weeks after ITx. Unexpectedly, there was no correlation between mRNA expression for IL-1beta in total blood and the number of lymphocytes and monocytes remaining after anti thymocyte globulin (ATG)-therapy. Even when the blood was nearly totally depleted from mononuclear cells, high amounts of IL-1beta mRNA could be detected. However, IL-1beta secretion could not be stimulated in vitro. Our results show that application of ATG during ITx might contribute to graft survival during the early posttransplant period by suppression of the synthesis of monocyte derived cytokines IL-1beta and TNFalpha.

Critical islet mass for successful porcine islet autotransplantation.

A major reason for the failure of clinical islet transplantations may be a limited islet mass. The aim of this study was to determine the critical islet mass necessary for normalization of glucose metabolism in a porcine model. Diabetes was induced by total pancreatectomy. The splenic lobe of the pancreas was intraductally distended with UW-solution containing 2.67-3.33 mg/ml collagenase, and the distended pancreas was digested in a continuous digestion filtration device. The islets were purified on a isoosmotic Ficoll-sodium-diatrizoate gradient. The survival period of the diabetic recipients in group 2 and 3 receiving, respectively, a low (2.14+/-0.39 microL/kg body weight) and a high (4.99+/-0.83 microL/kg body weight) islet mass was significantly prolonged compared to that of diabetic recipients in group 1 receiving no islet transplantation. However, the survival period of the recipients in group 2 was not significantly different to that in group 3. Three recipients of an islet mass of >5 microl/kg body weight became normoglycemic (fasting blood glucose <100 mg/dl) for more than two months. Furthermore, the glucose and insulin release reactions to the glucose challenge were comparable to that before pancreatectomy. Contrarily, another five diabetic recipients of an islet mass of <4 microL/kg body weight became a fasting blood glucose level of <200 mg/dl. The glucose and insulin release reactions to the glucose challenge were improved only, but not normalized compared to that before pancreatectomy. The data presented in this study demonstrate that metabolic normalization in pancreatectomized diabetic minipigs can be established by autotransplantation of an islet mass of >5 microl/kg body weight.

Viability and recovery of frozen-thawed human islets and in vivo quality control by xenotransplantation.

Cryopreservation of islets of Langerhans offers advantages for the transplantation into diabetic patients. In this study two different methods of cryopreservation were compared with respect to islet viability and recovery after cryostorage. It was also investigated whether human islet survival in mice was affected by cryopreservation. Aliquots of human islets were cryopreserved conventionally or vitrified, respectively. After rapid thawing, islet viability and islet equivalent (IEQ) recovery rate were determined. Aliquots of freshly isolated or conventionally cryopreserved islets were transplanted beneath the kidney capsule of non-diabetic C57BL/6 mice. After three days renal insulin content was determined. Islet cell viability was 17.3+/-8.0% for vitrified and 51.8+/-3.0% for conventionally cryopreserved islets; the recovery rate was 84.8+/-12.2% and 92.8+/-12.4%, respectively. Insulin recovery after transplantation was 25.6+/-7.3% for fresh and 24.1+/-7.4% for cryopreserved islets. This study suggests that the conventional method of cryopreservation is superior to vitrification with respect to islet viability after thawing. We found no significant difference between fresh and cryopreserved islets with respect to insulin recovery after transplantation into mice.

Isokinetic gradient centrifugation prolongs survival of pig islets xenografted into mice.

Highly purified porcine islets were prepared by isokinetic gradients performed subsequently to isopycnic gradients. This additional purification step separates ductal, vascular, and lymphoid tissue effectively from endocrine tissue. Although ductal, vascular, and lymphoid tissue comprises only a minor contamination of the islet suspensions, a significant prolongation of the survival of porcine islets xenografted into streptozotocin diabetic C57BL/6 mice can be achieved by the elimination of the non-endocrine tissue. Rejection after islet transplantation is delayed from 2.2+/-0.4 days (n=27) to 13.1+/-2.1 days (n=36), respectively, when conventionally purified and highly purified islets are compared. Irrespective of the purification state, pretreatment of islets by low temperature culture had no effect on xenograft survival.

Analysis of the cellular reaction towards microencapsulated xenogeneic islets after intraperitoneal transplantation.

Xenotransplantation of encapsulated islets of Langerhans is a possibility to overcome problems of human organ donor shortage in islet transplantation. Preexisting natural xenoantibodies are known to play a major role in the rejection of vascularized xenografts. Only little is known about the mechanism of rejection of non-vascularized cellular xenotransplants. In this study we introduce a method for the characterization of xenograft rejection of encapsulated islets by FACS analysis of peritoneal cells. Pig islets were transplanted intraperitoneally into non-diabetic Lewis rats either encapsulated or non-encapsulated. Animals receiving empty capsules and sham-operated animals served as controls. After 7 days a peritoneal lavage was performed. The total cell number and the viability of the cells were determined. Cells were analysed after staining with a panel of antibodies for the detection of T-lymphocytes, B-lymphocytes, macrophages, MHC class II molecules. Total cell number was highest after microencapsulated transplantation (149.4+/-30.1x10(6)) compared with empty capsules (41.4+/-19.7x10(6)) and non-encapsulated porcine islets (18.1+/-3.3x10(6)). The percentage of CD 3 positive T-lymphocytes rose to 44.5+/-11.5% in case of microencapsulated xenografts compared with 19.2+/-8.2% for non-encapsulated xenografts and 4.9+/-2.4% for empty controls. B-lymphocytes were detected in only small amounts. MHC class II expression on macrophages as activation marker was significantly increased after encapsulated transplantation (60.2+/-8.9% vs 15.2+/-7.0% for free islets and 4.9+/-1.2% for empty controls). The discrepancy between the macrophage activation due to encapsulated xenogeneic islets in comparison to empty capsules made from the same material clearly indicates that the reaction is not only material related but that a recognition of the encapsulated islet takes place despite the effective inhibition of a direct cell-to-cell contact. This recognition occurs on a T-cell level as well as on the macrophage level. 7 days after transplantation the reaction towards encapsulated xenografts is even more intense than to non-encapsulated xenografts. This might be due either to the time course of the rejection process or to a prolongation of the activation because antigen elimination is hindered by the capsule.

Effect of stable glutamine compounds on porcine islet culture.

BACKGROUND: Pig islets are characterized by significant fragility, preventing successful islet culture prior to xenotransplantation. To improve outcome after culture, we compared the effects of glutamine supplementation on survival and viability of isolated pig islets during culture. METHODS: Pig islets were suspended in CMRL 1066 supplemented either with 2.5 mmol/L N-acetyl-L-alanyl-L-glutamine (NALG), a stable compound of L-glutamine, or with 2.5 or 5.0 mmol/L of free L-glutamine (L-Glu). After 24 hours of preincubation, islets were stressed for additional 48 hours with H2O2, DETA, or a cytokine mix. RESULTS: Twenty-four-hour survival of unstressed controls precultured with 2.5 mmol/L NALG was significantly decreased compared with islets pretreated with 2.5 or 5.0 mmol/L L-Glu (P < .01). Fresh islets, viability decreased significantly after NALG preincubation, but was maintained after preincubation in 2.5 or 5.0 mmol/L L-Glu (not significant vs fresh; P < .05 vs NALG). Compared with NALG pretreatment L-Glu did not significantly ameliorate the relative survival (related to cultured controls) of islets during proinflammatory treatment. Nevertheless, the beneficial effect of L-Glu preculture on absolute survival (related to freshly isolated islets) of stressed islets was still present in contrast to NALG pretreatment (P < .01). Viability of stressed islets was significantly protected by L-Glu but not by NALG. CONCLUSIONS: Pig islet culture is significantly improved if L-glutamine is administered in an unbound form compared with the stable compound NALG. Stress resistance of pig islets seems to be increased by free L-glutamine as well.

Timing of hyperthermic preconditioning affects islet resistance against inflammation.

BACKGROUND: Heat exposure of isolated islets enhances resistance against inflammation but decreases islet graft function. In contrast, donor preconditioning by whole-body hyperthermia increases islet ischemic tolerance and improves viability of pancreatic isografts. This study aimed to compare yield, viability, and inflammatory resistance of rat islets subjected to heat shock prior to (pre-HS) or after isolation (post-HS). METHODS: Islets were isolated as previously described. HS (42 degrees C/45 min) was induced 12 hours before islet isolation (pre-HS, n = 31) or in freshly isolated islets prior to 12 hours of recovery at 37 degrees C (post-HS, n = 12). Islets continuously incubated at 37 degrees C served as controls (n = 33). Proinflammatory treatment included incubation with 0.05 mmol/L H(2)O(2), 1.0 mmol/L DETA-NO or cytokines (interleukin-1beta + tumor necrosis factoralpha + interferongamma). RESULTS: Purified islet yield was 1200 +/- 80 IEQ in unconditioned donors (n = 45) and 980 +/- 80 IEQ after pre-HS (ns). Islet viability was not affected by post-HS, but the glucose stimulation index (P < 0.001, P < 0.01) and formazan production (P < 0.05) were significantly lower compared to pre-HS or sham treatment. The expression of heat shock protein HSP70 in pre-HS islets was slightly higher compared to controls (ns) but lower compared to post-HS islets (P < 0.05), correlating with the resistance against H(2)O(2) and DETA-NO compared to post-HS islets (P < 0.05) or controls (ns). Cytokines did not affect mitochondrial formazan production. CONCLUSIONS: The findings indicate that hyperthermic islet treatment is less harmful if performed in the native pancreatic environment. This beneficial effect is associated with a decreased HSP70 expression resulting in a reduced resistance against inflammatory mechanisms.