Dissecting the instant blood-mediated inflammatory reaction in islet xenotransplantation

Abstract: Background: A massive destruction of transplanted tissue occurs immediately following transplantation of pancreatic islets from pig to non‐human primates. The detrimental instant blood‐mediated inflammatory reaction (IBMIR), triggered by the porcine islets, is a likely explanation for this tissue loss. This reaction may also be responsible for mediating an adaptive immune response in the recipient that requires a heavy immunosuppressive regimen. Materials and methods: Low molecular weight dextran sulfate (LMW‐DS) and the complement inhibitor Compstatin were used in a combination of in vitro and in vivo studies designed to dissect the xenogeneic IBMIR in a non‐human primate model of pancreatic islet transplantation. Adult porcine islets (10 000 IEQs/kg) were transplanted intraportally into three pairs of cynomolgus monkeys that had been treated with LMW‐DS or heparin (control), and the effects on the IBMIR were characterized. Porcine islets were also incubated in human blood plasma in vitro to assess complement inhibition by LMW‐DS and Compstatin. Results: Morphological scoring and immunohistochemical staining revealed that the severe islet destruction and macrophage, neutrophilic granulocyte, and T‐cell infiltration observed in the control (heparin‐treated) animals were abrogated in the LMW‐DS‐treated monkeys. Both coagulation and complement activation were significantly reduced in monkeys treated with LMW‐DS, but IgM and complement fragments were still found on the islet surface. This residual complement activation could be inhibited by Compstatin in vitro. Conclusions: The xenogeneic IBMIR in this non‐human primate model is characterized by an immediate binding of antibodies that triggers deleterious complement activation and a subsequent clotting reaction that leads to further complement activation. The effectiveness of LMW‐DS (in vivo and in vitro) and Compstatin (in vitro) in inhibiting this IBMIR provides the basis for a protocol that can be used to abrogate the IBMIR in pig‐human clinical islet transplantation.     

Reduction of early graft loss after intraportal porcine islet transplantation in monkeys

BACKGROUND: Pig islets constitute a possible resolution to the shortage of human islets for transplantation. After intraportal infusion of porcine islets in primates, many islets are lost through what has been termed the instant blood-mediated inflammatory reaction (IBMIR). We report on our experience with IBMIR. METHODS: Ten monkeys underwent intraportal porcine islet transplantation. Immunosuppressive therapy was with conventional agents (n=3) or based on costimulation blockade (n=7). Treatment specific for IBMIR was administered in eight monkeys; two additional monkeys received no such therapy (group 1). Cobra venom factor completely inhibited complement activity in four (group 2) and dextran sulfate provided anticoagulation in four (group 3). Islet graft function was monitored by following blood glucose, insulin requirement, and porcine C-peptide values. RESULTS: In monkeys that received neither cobra venom factor nor dextran sulfate (group 1), there was rapid destruction of islets indicated by severe hypoglycemia and the need for dextrose infusion; C-peptide levels were initially low and further reduction occurred within the first five days. In both groups 2 and 3, there was significantly less destruction of islets and some reversal of diabetes. However, when 40,000 IEQ/kg were infused, normoglycemia was lost within five days, but when 80,000 IEQ/kg were infused in one case, normoglycemia was more persistent. We observed that even when C-peptide levels were in the normal range for healthy nondiabetic pigs, these were not sufficient to maintain normoglycemia in the monkeys. CONCLUSIONS: Although pretransplantation complement depletion or anticoagulation reduces porcine islet xenograft loss significantly, neither alone is sufficient to prevent IBMIR.     

Transplantation of mouse pancreatic islets into primates--in vivo and in vitro evaluation.

BACKGROUND: Islets transplanted from other species to man has the potential to cure diabetes but whether islets are subject to hyperacute rejection after xenotransplantation is contentious. We transplanted mouse pancreatic islets of mouse beneath the primate renal capsule and assessed natural xenoantibody binding, complement activation and cell lysis in vitro. METHODS: Freshly isolated mouse islets were transplanted in a blood clot under the renal capsule of cynolmogus monkeys. The graft was removed after 24 hr for histological and ultrastructural analysis. Freshly isolated mouse pancreatic islets were analyzed in vitro by immunohistochemistry for Gal(alpha1,3)Gal and Von Willebrand factor expression and for IgG, IgM, C3, C4, and C5b-9 binding after incubation in 100% human serum. Complement mediated cell lysis was evaluated by 51Cr release assays after incubation of islets for 4 hr in human serum, plasma, and lymph with and without added neutrophils. RESULTS: Mouse islets transplanted under the renal capsule of cynomolgus monkeys were destroyed within 24 hr by a process involving necrosis with neutrophil and mononuclear cell infiltration. Gal(alpha1,3)Gal was strongly positive on only 10% of islet cells. After islet incubation in 100% human serum before frozen section, human IgG and IgM, C3, C4, and C5b-9 was deposited on islets with increased intensity in the periphery. Measurement of 51Cr release from labeled fresh islets after four hours incubation in 100% human serum showed 17% lysis and was not changed by addition of neutrophils. CONCLUSION: These results indicate that mouse islets in a primate recipient undergo rapid destruction by a process that has features similar to hyperacute rejection in vascularized organs and we propose the same term be used.     

胰岛移植术后立即经血液介导的炎症反应机制

目的初步探讨胰岛移植术后立即经血液介导的炎症反应(instant blood-mediated in-flammatory reaction,IBMIR)的发生机制。方法Wistar大鼠,雌雄不限,体重为250～300g,分离、纯化胰岛,建立体外循环模型,于37℃下循环反应60min后加入胰岛800当量模拟IBMIR,分别于循环前、加入胰岛前、加入胰岛后5min、15min、30min、60min后留取血液行血常规检测,用酶标法检测血浆凝血酶-抗凝血酶复合物(thrombin-antithrombin complex,TAT),并用酶联免疫吸附法检查血浆补体3a(C3a)含量。循环60min后取过滤残余血栓和组织行形态学检查。结果加入胰岛体外循环60min后血液中的血小板几乎全部耗竭,白细胞及单核细胞减少亦较为明显,但淋巴细胞比例变化不明显。血浆中的TAT、C3a含量随循环时间延长而增加。循环60min后的过滤残余的血栓块和组织中胰岛数量较少,结构破坏严重,被膜不完整,胰岛周围被微血栓包绕,大量中性粒细胞浸润。结论凝血反应、补体激活和白细胞激活可能是导致IBMIR的重要机制。     

Low molecular weight dextran sulfate prevents the instant blood-mediated inflammatory reaction induced by adult porcine islets

BACKGROUND: One of the main obstacles to clinical islet xenotransplantation is the injurious instant blood-mediated inflammatory reaction (IBMIR) that causes rapid binding of platelets to the islet surface, activation of the coagulation and complement systems, and leukocyte infiltration of the islets when the islets are exposed to blood. METHODS: This study assesses the effect of low molecular weight dextran sulfate (LMW-DS) on IBMIR induced by porcine islets in an in vitro tubing loop assay using human blood and in an in vivo model using diabetic athymic mice. RESULTS: In vitro experiments demonstrated that platelet consumption, coagulation, and complement activation were already reduced in the presence of LMW-DS at 0.01 mg/mL, and that at 0.1 mg/mL, LMW-DS prevented IBMIR. Immunohistochemical investigation showed that the leukocyte infiltration was abrogated at the highest dose. In vivo experiments showed that the transplanted pig islets survived for a significantly longer period in recipients treated with LMW-DS, and morphologic examination of transplanted islets showed a reduction in IBMIR analogous to that demonstrated by in vitro studies. CONCLUSIONS: Given that LMW-DS has been used in clinical studies without serious adverse reactions, it has potential as a drug candidate that can control the strong innate immune response induced by pig islets when transplanted through the portal vein.     

Composite Islet-Endothelial Cell Grafts: A Novel Approach to Counteract Innate Immunity in Islet Transplantation

An instant blood-mediated inflammatory reaction (IBMIR) is elicited when islets come in contact with blood after intraportal transplantation. In contrast, endothelial cells (EC) readily tolerate contact with blood. A conceivable strategy to overcome IBMIR would be to create composite islet-EC grafts. Human islets were co-cultured with primary human aortic endothelial cells (HAEC) for 2-7 days to obtain 50-90% coverage. HAEC-coated islets were exposed to ABO-identical blood and analyzed with regard to clotting time, signs of inflammation and cell infiltration. Composite islet-HAEC graft survival was assessed after transplantation to athymic (nu/nu) nude mice. Exposed to blood, HAEC-coated islets induced less activation of coagulation and complement compared to control islets. Also, platelet and leukocyte consumption in blood was decreased. Clots with entrapped HAEC-coated islets showed less infiltration of CD11b+ cells. The extent of protection correlated to the level of HAEC coverage. Transplanted composite grafts stained positive for insulin and PECAM-1 demonstrating presence of both islets and HAEC within the islet graft 7 weeks after transplantation. Composite islet-HAEC grafts reduce all components of IBMIR. Refinement of the technique will allow introduction of composite islet-EC grafts in clinical islet transplantation, using autologous EC expanded in vitro and kept frozen until allogeneic islets become available for that specific recipient.     

Six-month survival of microencapsulated pig islets and alginate biocompatibility in primates: proof of concept

BACKGROUND: Pig islets xenotransplantation remains associated with a strong humoral and cellular xenogeneic immune responses. The aim of this study was to assess the long-term biocompatibility of alginate encapsulated pig islets after transplantation in primates. METHODS: Adult pig islets encapsulated in alginate under optimal conditions (n=7) or not (n=5) were transplanted under the kidney capsule of nondiabetic Cynomolgus maccacus. Additional primates received empty capsules (n=1) and nonencapsulated pig islets (n=2) as controls. Capsule integrity, cellular overgrowth, pig islet survival, porcine C-peptide and anti-pig IgM/IgG antibodies were examined up to 6 months after implantation. RESULTS: Nonencapsulated islets and islets encapsulated in nonoptimal capsules were rapidly destroyed. In seven primates receiving perfectly encapsulated pig islets, part of the islets survived up to 6 months after implantation without immunosuppression. Porcine C-peptide was detected after 1 month in 71% of the animals. The majority of grafts (86%) were intact and completely free of cellular overgrowth or capsule fibrosis. Explanted capsules, after 135 (n=2/2) and 180 (n=2/3) days, demonstrated residual insulin content and responses to glucose challenge (stimulation index of 2.2). Partial islet survival was obtained despite an elicited anti-pig IgG humoral response. CONCLUSIONS: Optimal alginate encapsulation significantly prolonged adult pig islet survival into primates for up to 6 months, even in the presence of antibody response.     

Long-term survival and function of intraportal porcine and human islet xenografts in nondiabetic nude mice

Instant blood-mediated inflammatory reaction (IBMIR) is a serious obstacle to both clinical islet allotransplantation and future islet xenotransplantation via the portal vein. We have previously observed uniform long-term tilapia (fish) islet xenograft survival when islets were transplanted intraportally into nondiabetic nude mice (nDNM), but not in diabetic nude mice (DNM). In this study, we examined whether human islets (HI) and adult porcine islets (API) can tolerate intraportal transplantation into nDNM like tilapia islets. HI and API were transplanted intraportally into nDNM. Recipients were humanely killed either 14 or 28 days after transplantation and livers were processed for histology. Human insulin and human C-peptide were measured in the terminal serum samples of HI recipients. In six of seven HI and seven of seven API recipients, liver histology showed insulin-positive islet xenografts. In recipients with HI, the numbers of islets/ductal structures seen histologically correlated well with serum sample results. These results show that HI and API can survive and function long term after intraportal transplantation into nDNM recipients. Our previous and present data indicated that DNM and nDNM could be useful models to study "glucose toxicity" and the role of IBMIR in the fate of intraportal islet grafts.     

Tissue factor produced by the endocrine cells of the islets of Langerhans is associated with a negative outcome of clinical islet transplantation

There are strong indications that only a small fraction of grafts successfully engraft in clinical islet transplantation. One explanation may be the instant blood-mediated inflammatory reaction (IBMIR) elicited by tissue factor, which is produced by the endocrine cells. In the present study, we show that islets intended for islet transplantation produce tissue factor in both the transmembrane and the alternatively spliced form and that the membrane-bound form is released as microparticles often associated with both insulin and glucagon granules. A low-molecular mass factor VIIa (FVIIa) inhibitor that indirectly blocks both forms of tissue factor was shown in vitro to be a promising drug to eliminate the IBMIR. Thrombin-antithrombin complex (TAT) and FVIIa-antithrombin complex (FVIIa-AT) were measured in nine patients who together received 20 infusions of isolated human islets. Both the TAT and FVIIa-AT complexes increased rapidly within 15-60 min after infusion. When the initial TAT and FVIIa-AT levels were plotted against the increase in C-peptide concentration after 7 days, patients with an initially strong IBMIR showed no significant increase in insulin synthesis after 7 days. In conclusion, tissue factor present in both the islets and the culture medium and elicits IBMIR, which affects the function of the transplanted islets.     

Inhibition of thrombin abrogates the instant blood-mediated inflammatory reaction triggered by isolated human islets: possible application of the thrombin inhibitor melagatran in clinical islet transplantation

A thrombotic/inflammatory reaction is elicited when isolated islets of Langerhans come in contact with ABO-compatible blood. The detrimental effects of this instant blood-mediated inflammatory reaction (IBMIR) provide a reasonable explanation for the observation that an unexpectedly high number of islets, from several donors, are needed to produce normoglycemia in transplant patients with type 1 diabetes. In this study, the hypothesis that a specific thrombin inhibitor, Melagatran, could reduce IBMIR in an in vitro model in which human islets are exposed to ABO-compatible blood was tested. The administration of Melagatran abrogated IBMIR dose-dependently. Islets exposed to blood, in the absence or presence of 0.4 micromol/l Melagatran, exhibited a loss of integrity and were found to be trapped in macroscopic clots containing platelets and CD11b(+) leukocytes. At concentrations from 1 to 10 micromol/l, Melagatran inhibited both coagulation and complement activation. Also, platelet and leukocyte activation and consumption were decreased. Islet morphology was maintained with almost no platelets adhering to the surface, and infiltration by CD11b(+) leukocytes was considerably reduced. In conclusion, Melagatran significantly reduced IBMIR in this model system. This protective effect indicates that thrombin plays a pivotal role in IBMIR and suggests that thrombin inhibition can improve the outcome of clinical islet transplantation.     

Rapid loss of intraportally transplanted islets: an overview of pathophysiology and preventive strategies

Islets isolated from multiple pancreas donors are often necessary to achieve euglycemia in type 1 diabetic patients treated by islet allotransplantation. This increases the burden on the limited pool of donor organs. After infusion into the portal vein, a substantial percentage of islets are lost in the immediate post-transplant period through an inflammatory response termed the instant blood-mediated inflammatory reaction (IBMIR). IBMIR is equally, if not more of a problem after islet xenotransplantation, e.g., using pig islets in non-human primates. Coagulation, platelet aggregation, complement activation, and neutrophil and monocyte infiltration play roles in this reaction. IBMIR is potentially triggered by islet surface molecules, such as tissue factor and collagen residues that are normally not in direct contact with the blood. Also, stress during the islet isolation process results in the expression and production of several inflammatory mediators by the islets themselves. The potential mechanisms involved in this rapid graft loss and treatment options to reduce this loss are reviewed. Preventive strategies for IBMIR can include systemic treatment of the recipient, pre-conditioning of the isolated islets, or, in the case of xenotransplantation, genetic modification of the organ-source pig. Pre-conditioning of islets in culture by exposure to anti-inflammatory agents or by genetic modification harbors fewer risks of systemic complications in the recipient. The future of clinical islet transplantation will, at least in part, depend on the success of efforts made to reduce rapid graft loss, and thus allow islet transplantation to become a more efficient therapy by the use of single donors.     

Clearance of complement by human vascular endothelial cells: effects of hypoxia/reoxygenation and IL-1β activation

Antibody-mediated rejection is characterized by deposits of complement (C) C4 and C3 split products on endothelial cells (ECs). C3 split products are critical mechanistically and diagnostically because they are deposited in amplified quantities, bind covalently to ECs and act as ligands for leukocytes. This study was designed to determine whether cultured vascular human ECs could clear covalently bound C3 split products from their surface. An immunoglobulin M (IgM) antibody against beta(2)-microglobulin of major histocompatibility complex class I antigens was used to activate C in human serum. Some cells were exposed to hypoxia/reoxygenation and/or interleukin 1beta (IL-1beta) prior to incubation with antibody. C3b/iC3b and C3d deposition on the cell surface was measured by flow cytometry. Incubation with antibody followed by human serum caused a dose-dependent deposition of C3b/iC3b and C3d. Over half of deposited C3b/iC3b and one-third of C3d were cleared from the cell surface during a 3-7-h incubation period with human serum. Neither hypoxia/reoxygenation nor IL-1beta further increased the deposition of C3b/iC3b and C3d, and only slightly modulated their rates of clearance. In summary, human ECs rapidly clear iC3b and C3d from their surface. This finding may have important diagnostic and mechanistic implications to transplantation because C3d is used as a marker of antibody-mediated rejection.     

Low-molecular weight dextran sulfate abrogates the instant blood-mediated inflammatory reaction induced by adult porcine islets both in vitro and in vivo

BACKGROUND: One of the main obstacles to clinical application of islet xenotransplantation is the injurious inflammatory reaction elicited by porcine islets when they are exposed to fresh human blood in vitro and in vivo. This instant blood-mediated inflammatory reaction (IBMIR) causes rapid binding of platelets to the islet surface, activation of the coagulation and complement systems, and leukocyte infiltration of the islets. As a consequence of IBMIR, morphological destruction of porcine islets occurs within the first few hours after transplantation. MATERIALS AND METHODS: In the present study, by analyzing the plasma samples and performing immunohistochemical investigation, we assessed the effect of adding low-molecular weight dextran sulfate (LMW-DS) at 0.01-1 mg/mL to an in vitro tubing loop assay in which porcine islets were exposed to fresh human blood. The effect of LMW-DS also was investigated in an in vivo model using diabetic athymic mice, which provides an innate inflammatory milieu without influence of T cells. The possible toxicity of LMW-DS was assessed by culturing pig islets in the presence or absence of LMW-DS for 3 days. RESULTS: In the in vitro study, in the presence of LMW-DS at 0.01 mg/mL, platelet consumption, coagulation, and complement activation were reduced, and, at 0.1 mg/mL, LMW-DS totally prevented IBMIR. Immunohistochemical investigation showed that leukocyte infiltration was totally abrogated at the highest dose. A similar finding was observed in the in vivo study. No adverse effect of LMW-DS was observed on the quality of the islets. CONCLUSIONS: LMW-DS appears to be an effective drug candidate that is able to control the strong innate immune response induced by pig islets in contact with human blood.     

Intraportal pig islet xenotransplantation into athymic mice as an in vivo model for the study of the instant blood-mediated inflammatory reaction

Abstract:  One of the main obstacles to successful intraportal islet transplantation is the instant blood-mediated inflammatory reaction (IBMIR) elicited by the isolated islets when exposed to fresh human blood. In the present study, we investigated whether intraportal transplantation of pig islets into diabetic athymic mice could be used as a small animal model to study xenogeneic IBMIR in vivo.
Adult porcine islets (APIs) or rat islets were implanted into the portal vein or under the renal subcapsular space of diabetic athymic mice. Graft survival and morphology were evaluated by measuring blood glucose levels and by performing immunohistochemical staining, respectively. Transplantation of rat islets, irrespective of implantation site, cured all diabetic athymic mice. APIs transplanted subcapsularly also cured all diabetic athymic mice, while none of the animals transplanted with an equivalent amount of APIs via the portal vein remained normoglycemic for more than 10 days after transplantation. Immunohistochemical staining on day 7 showed that most of intraportally transplanted APIs were entrapped in clots and infiltrated with CD11b+ leukocytes. Intraportal transplantation of APIs into athymic mice induced IBMIR, thus providing a small animal model for studying xenogeneic IBMIR.     

Interference with tissue factor prolongs intrahepatic islet allograft survival in a nonhuman primate marginal mass model

BACKGROUND: Tissue factor (TF) expression on islets can result in an instant blood-mediated inflammatory reaction (IBMIR) that contributes to early islet loss. We tested whether peritransplant protection of islets from IBMIR with a monoclonal anti-TF antibody (CNTO859) would enhance engraftment in our nonhuman primate marginal mass model. METHODS: Each of six pairs of cynomolgus monkeys (CM) with streptozotocin-induced diabetes was closely matched for metabolic control and was transplanted with 5,000 IEQ/kg allogeneic, ABO-compatible islets from the same donor under the cover of steroid-free immunosuppression. For each pair, experimental animals received islets cultured with 20 microg/mL anti-TF and were dosed with 6 mg/kg anti-TF intravenously, 10-25 min before islet infusion; control monkeys received an equal number of islets from the same preparation cultured without anti-TF and no in vivo treatment. RESULTS: Early fasting C-peptide (CP) values were different between (P<0.01), but not within, pairs and correlated with in vitro functional capacity of islets as assessed by perifusion (r=0.60; P=0.022). Compared to their matched controls, experimental animals had decreased posttransplant markers of coagulation, higher fasting CP levels (1 month posttransplant and end of study) and prolonged graft function. CONCLUSIONS: These data suggest that pretreatment of islets and the recipient with anti-TF may limit the effects of IBMIR, thereby enhancing islet engraftment and survival.     

Tissue factor knockdown in porcine islets: an effective approach to suppressing the instant blood-mediated inflammatory reaction

Tissue factor (TF) expression on islets has been shown to trigger instant blood-mediated inflammatory reaction (IBMIR), leading to rapid islet loss in portal vein islet transplantation. This study investigated whether antisense RNA-mediated TF gene knockdown in islets could suppress IBMIR as a strategy to overcome IBMIR. Neonatal porcine islet cell clusters (NICCs) were transfected with or without TF-specific antisense RNA or a nonspecific RNA by a lipid-based method. Expression of both TF gene and protein in NICCs was analyzed after transfection by real-time PCR, Western blot, and FACS, respectively. The impact of antisense RNA transfection on NICC viability and in vitro function was examined by FACS and insulin release test, respectively. The effect of TF knockdown in NICCs on IBMIR was assessed with an in vitro tubing loop assay using human blood. A significant reduction in TF gene and protein expression was achieved in TF antisense RNA but not control RNA transfected NICCs, which did not affect NICCs' viability or their insulin secreting capacity. Incubation of TF antisense RNA transfected with human blood resulted in a considerable reduction in blood clot formation, platelet consumption, and complement and coagulation activation compared to that observed in the loops containing human blood and untreated or control RNA transfected NICCs. Consistent with these findings, infiltrating neutrophils in the blood clots with entrapped TF antisense RNA transfected NICCs was also reduced substantially compared to that seen in the clots containing untreated or control RNA transfected NICCs. This study presents a nontoxic TF antisense RNA-mediated TF knockdown in porcine islets that leads to an effective suppression of IBMIR, suggesting a potentially new strategy to improve islet transplantation outcomes.     

Endoscopic Gastric Submucosal Transplantation of Islets (ENDO-STI): Technique and Initial Results in Diabetic Pigs

The results of transplantation of human donor islets into the portal vein (PV) in patients with diabetes are encouraging. However, there are complications, for example, hemorrhage, thrombosis and an immediate loss of islets through the 'instant blood-mediated inflammatory reaction' (IBMIR). The gastric submucosal space (GSMS) offers potential advantages. Islets were isolated from adult pigs. Recipient pigs were made diabetic by streptozotocin. Donor islets were injected into the GSMS through a laparotomy (Group 1A, n = 4) or endoscopically (Group 1B, n = 8) or into the PV through a laparotomy (Group 2, n = 3). The pigs were followed for a maximum of 28 days. Monitoring of C-peptide in Group 1 indicated that there was minimal immediate loss of islets whereas in Group 2 there was considerable loss from IBMIR. In Group 1, there were significant reductions in mean blood glucose and mean exogenous insulin requirement between pretransplantation and 20 days posttransplantation. In Group 2, there was no significant reduction in either parameter. Insulin-positive cells were seen in the GSMS in Group 1, but not in the liver in Group 2. Endoscopic gastric submucosal transplantation of islets (ENDO-STI) offers a minimally invasive and quick approach to islet transplantation, avoids IBMIR and warrants further exploration.     

胰岛细胞移植后发生立即经血液介导的炎症反应的机制

在胰岛细胞移植的过程中,当其一接触受体血液即会引发立即经血液介导的炎症反应(IBMIR),使胰岛细胞迅速破坏失去分泌胰岛素的功能,笔者就IBMIR发生机制所涉及的问题,包括凝血系统的激活、补体系统的激活和抗体的作用、炎症介质和炎症细胞的浸润以及葡萄糖毒性的作用等作一综述。     

Damage to porcine islets of Langerhans after exposure to human blood in vitro, or after intraportal transplantation to cynomologus monkeys: protective effects of sCR1 and heparin

BACKGROUND: Porcine islets offer an attractive alternative to human islets in clinical islet transplantation. The preferred method of islet transplantation is intra-portal injection into the liver. We have recently shown, both in vitro with human islets and in vivo with porcine islets, that islets exposed to allogeneic blood trigger an injurious inflammatory reaction characterized by activation of both coagulation and the complement systems. We have now tested whether a similar reaction is triggered when xenogeneic porcine islets are exposed to human blood in vitro and after intraportal transplantation into primates. Furthermore, we investigated the effect of inhibiting the complement and coagulation systems. METHOD: Islets isolated from adult and fetal porcine pancreas were perfused with fresh human blood in surface heparinized PVC tubings for 5-60 min. Blood cell counts and parameters related to coagulation and the complement system were analyzed, and islets were retrieved after the perifusion was examined by immunohistochemical method. Heparin and soluble complement receptor 1 (sCR1; TP10, 100 microg/ml) were added to the system in some experiments. Furthermore, adult porcine islets were transplanted intraportally into untreated and sCR1- (40 mg/kg BW i.v.) treated cynomolgus monkeys, and plasma insulin concentration was monitored during 60 min after transplantation. RESULTS: Porcine islets perifused with human blood triggered an immediate inflammatory reaction, characterized by a rapid consumption and activation of platelets, consumption of neutrophils and monocytes, activation of the coagulation and complement systems, and release of large amounts of insulin. Islet morphologic analysis revealed damaged islets embedded in clots and infiltrated with CD11+ leukocytes. C3a and C5b-9 was deposited on the islet surface, but human immunoglobulin was not. Complement inhibition with sCR1 reduced insulin release significantly. Intraportal islet transplantation into untreated cynomolgus monkeys resulted in a marked and rapid increase in plasma insulin concentration indicative of islet damage. Pretreatment of the monkeys with sCR1 resulted in significantly less insulin release than in untreated control monkeys. CONCLUSION: Exposure of isolated xenogeneic islets of Langerhans to blood, both in vitro and in vivo, resulted in acute islet damage. Complement and platelets seem to have a central role in the reactions described. Strategies to efficiently inhibit these reactions will be crucial for clinical intraportal islet xenotransplantation to be successful.     

Low Molecular Weight Dextran Sulfate: A Strong Candidate Drug to Block IBMIR in Clinical Islet Transplantation

The instant blood-mediated inflammatory reaction (IBMIR) is triggered in clinical islet transplantation when human pancreatic islets come in contact with blood and may explain the initial tissue loss associated with this procedure. Low molecular weight dextran sulfate (LMW-DS; MM 5000), today available for clinical use, inhibits both complement and coagulation activation. In a tubing loop model, LMW-DS at concentrations ranging from 0.01 to 1 g/L showed a dose-dependent inhibition of IBMIR with an inhibition of coagulation and complement activation and less consumption of platelets and other blood cells. In blood or plasma APTT was demonstrated to be an excellent method for monitoring the LMW-DS concentration both in vitro and in vivo in a nonhuman primate model. The toxicity was assessed using a glucose challenge test and the pharmacokinetics was tested in the nonhuman primate model. Here, we present a tentative protocol for using LMW-DS in clinical islet transplantation.