Bioengineering the Endocrine Pancreas: Intraomental Islet Transplantation Within a Biologic Resorbable Scaffold
Transplantation of pancreatic islets is a therapeutic option to preserve or restore β-cell function. Our study was aimed at developing a clinically applicable protocol for extrahepatic transplantation of pancreatic islets. The potency of islets implanted onto the omentum, using an in situ–generated adherent, resorbable plasma-thrombin biologic scaffold, was evaluated in diabetic rat and nonhuman primate (NHP) models. Intraomental islet engraftment in the biologic scaffold was confirmed by achievement of improved metabolic function and preservation of islet cytoarchitecture, with reconstitution of rich intrainsular vascular networks in both species. Long-term nonfasting normoglycemia and adequate glucose clearance (tolerance tests) were achieved in both intrahepatic and intraomental sites in rats. Intraomental graft recipients displayed lower levels of serum biomarkers of islet distress (e.g., acute serum insulin) and inflammation (e.g., leptin and α2-macroglobulin). Importantly, low-purity (30:70% endocrine:exocrine) syngeneic rat islet preparations displayed function equivalent to that of pure (>95% endocrine) preparations after intraomental biologic scaffold implantation. Moreover, the biologic scaffold sustained allogeneic islet engraftment in immunosuppressed recipients. Collectively, our feasibility/efficacy data, along with the simplicity of the procedure and the safety of the biologic scaffold components, represented sufficient preclinical testing to proceed to a pilot phase I/II clinical trial.
Intrahepatic islet transplantation has been the gold standard for clinical islet transplantation trials aimed at treating patients with type 1 diabetes (T1D) and hypoglycemia unawareness or with surgically induced diabetes (pancreatectomy) (1). It has resulted in normalization of hemoglobin A1c, improved glycemic control, and elimination of severe hypoglycemic events, even in the absence of insulin independence (2). Progressive graft dysfunction has been observed in clinical trials years after intrahepatic islet transplantation, often requiring reintroduction of exogenous insulin. Long-term intrahepatic islet dysfunction has been also observed in preclinical models (3). Activation of an immediate blood-mediated inflammatory reaction (IBMIR) and hypoxia in the transplant microenvironment after intrahepatic islet embolization contributes to functional impairment and the loss of a significant portion of the transplanted islets (4–7). Furthermore, the hepatic first pass of orally administered drugs exposes intrahepatic islets to higher concentrations of diabetogenic immunosuppressive agents. Other potential challenging factors in this setting include accumulation of peri-insular fat (microsteatosis) in the liver parenchyma (8–13). Moreover, chronic exposure of intrahepatic islets to endotoxins and other proinflammatory agents absorbed through the gastrointestinal tract, in addition to the IBMIR, may trigger adaptive immune responses that are known to be associated with a higher incidence of acute and chronic rejection episodes, as well as possibly facilitate recurrence of autoimmunity in transplanted subjects with T1D (2).
The final objective of developing an extrahepatic site for islet transplantation is not only the ability to provide physiologic portal drainage of endocrine pancreas secretions but also the possibility of engineering the transplant microenvironment for the development of successful biologic replacement strategies that could avoid the need for chronic recipient immunosuppression (14,15). Ideal characteristics of such a site include sufficient space to accommodate relatively large tissue volumes (e.g., low-purity or encapsulated insulin-producing cell products), allow for minimally invasive transplant procedures, and enable noninvasive longitudinal monitoring and access for graft biopsy and/or retrieval, as well as physiologic venous drainage through the portal system (14,15). An additional advantage is the reportedly immunomodulatory effect of antigens delivered though the portal venous system (portal tolerance) that was associated with lower rejection rates in pancreas transplants with portal versus systemically drained organs (16).
The omentum is easy to mobilize and adequately large to accommodate islet grafts (300–1,500 cm2 surface area in humans) (17,18). It is composed of two mesothelial sheets containing rich capillary networks draining into the portal venous system (19–21). Furthermore, intraomental islet implantation was shown to improve metabolic control in diabetic animal models (22,23).
We engineered a biologic scaffold by using plasma and recombinant human thrombin (rhT), a serine protease (factor IIa in the coagulation cascade) that catalyzes the conversion of plasma fibrinogen into fibrin that polymerizes forming a clot. The intraomental site was tested by implanting islets, embedded in situ into the resorbable biologic scaffold, on the omentum of diabetic rat and nonhuman primate (NHP) models with streptozotocin-induced diabetes. Our data support the feasibility of the approach that is currently in phase I/II clinical trials.
Research Design and Methods
Studies involving animal subjects were performed under protocols approved and monitored by the University of Miami (UM) Institutional Animal Care and Use Committee. Animals were housed at the Division of Veterinary Resources. Lewis (MHC, rat haplotype: RT1l) and Wistar Furth (WF) (RT1u) rats (http://www.harlan.com) were used as islet donors (>250 g males) and Lewis rats as recipients (170–200 g females). For selected experiments, rats with an indwelling jugular vein catheter (JVC) were purchased. Rodents were housed in microisolated cages with free access to autoclaved water and food. Both donor and recipient cynomolgus monkeys (7.92 and 3.58 years old, respectively) were obtained from the Mannheimer Foundation (Homestead, FL) and were specific pathogen free. Pair-housed monkeys were supplied with water ad libitum and fed twice daily (24). UM holds Animal Welfare Assurance A-3224-01, effective 12 April 2002, with the Office of Laboratory Animal Welfare, National Institutes of Health, and is accredited by the Association for Assessment and Accreditation of Laboratory Animal Care.
Diabetes Induction and Metabolic Monitoring
Rodents with nonfasting glycemic values ≥300 mg/dL on whole blood samples obtained from tail pricking (OneTouch Ultra glucometers [http://www.lifescan.com]) were used as recipients. Graft function was defined as nonfasting glycemia <200 mg/dL. At selected time points after transplantation, a glucose tolerance test was performed in rodents to evaluate graft potency (25). After overnight fasting, an oral (oral glucose tolerance test [OGTT]; 2.5 g/kg) or intravenous (intravenous glucose tolerance test [IVGTT]; 0.5 g/kg) glucose bolus was administered, and glycemic values were monitored with portable glucometers. The area under the curve (AUC) of glucose was calculated as previously described (26). In the case of allogeneic islet transplants, return to nonfasting hyperglycemic state was considered a sign of graft rejection.
In NHP, diabetes was defined as fasting C-peptide levels <0.2 ng/mL and a negative response (stimulated C-peptide <0.3 ng/mL) to a glucagon challenge performed 4 weeks after streptozotocin treatment (7,22). Heel-stick glycemic values were monitored two to three times daily (OneTouch Ultra). Subcutaneous insulin (Humulin R [https://www.lilly.com] or Humulin R plus Lantus [http://www.sanofi.us]) was administered based on an individualized sliding scale as needed, aiming for fasting blood glucose (FBG) and postprandial plasma blood glucose (PBG) levels of 150–250 mg/dL poststreptozotocin and prior to transplantation. Plasma C-peptide levels were assessed by electrochemiluminescence immunoassay using a Cobas analyzer (https://usdiagnostics.roche.com).
Blood obtained from venipuncture was collected into microcentrifuge tubes containing 3.2% sodium citrate. Plasma was obtained after centrifugation at 1,455g for 10 min at room temperature, and aliquots were stored at −80°C and thawed before use.
Islet Isolation and Graft Preparation
Islets were obtained by enzymatic digestion, followed by purification on density gradients using protocols standardized at the Diabetes Research Institute (DRI) for rats (DRI Translational Core) (27), NHP (22), and humans (DRI cGMP Human Cell Processing Facility) (1,28–30).
For evaluation of the effect of the degree of islet preparation purity on intraomental engraftment and function, Lewis rat islets were isolated and purified using a standard technique (27), yielding >95% purity (pure fraction) as assessed by dithizone staining (Sigma-Aldrich) (1,2). The pancreatic slurry containing exocrine tissue clusters (lowest purity fraction) after islet purification was maintained in culture and counted with the algorithm used to determine islet equivalents (IEQ) (2). Before transplantation, an aliquot of the final pure islet product was mixed with the exocrine pancreatic tissue to obtain a 30% pure islet cell product (3:7 v/v, islet vs. exocrine tissue).
Under general anesthesia, a substernal midline minilaparotomy allowed exteriorizing the omentum that was spread flat over a sterile field (Fig. 1). We previously reported a similar intraomental flap transplant procedure in NHP (22).
The rhT (Recothrom, National Drug Code no. 28400 [http://www.zymogenetics.com]) was reconstituted with the 0.9% NaCl included in the kit for rodents or with Dulbecco PBS with Ca2+/Mg2+ (GIBCO [http://www.thermofisher.com]) in the NHP experiment. Final aliquots of rhT (1,000 IU/mL) were stored at −20°C.
The transplantation procedure with the in situ generation of the islet-containing biologic scaffold is summarized in Fig. 1. For rodent experiments, islet aliquots were centrifuged (1 min, 200g), supernatant was discarded, and islets were resuspended in syngeneic (autologous) plasma. After another centrifugation, most of the excess plasma was removed and the slurry of islets/plasma collected with a precision syringe (hamiltoncompany.com). Similarly, in the case of the NHP, islets were collected into a microcentrifuge tube, quick spun and washed twice in donor plasma (obtained on day −1, stored at 4°C), and transported to the operating room. Plasma excess was removed before collection of islets/plasma with use of a micropipette (P1000). In both species, the islets/plasma slurry was gently distributed onto the surface of the omentum (Fig. 1A, b2, and c3) and then rhT gently dripped onto the graft (Fig. 1A, c4), resulting in immediate gelling and adherence of the islets to the omental surface. The omentum was gently folded on itself to increase contact with and containment of the graft (Fig. 1A, b3, b4, and c5). In the NHP, nonresorbable sutures were placed on the omentum outside the graft area as reference for the time of retrieval (Fig. 1, c5). In rodent experiments, nothing, sutures, or a plasma:rhT mix (10:1 v/v) was used on the folded omentum. After repositioning the omentum into the peritoneal cavity, abdominal wall muscle and skin were sutured.
To avoid the potential confounding effect of variability in islet preparations (31), for rat experiments aimed at comparison of transplant sites or purity, equal numbers of syngeneic islets, from large batch isolations, were implanted in parallel into diabetic recipients in a biologic scaffold or into the liver (25). In selected rats, survival surgery to remove graft-bearing omentum after long-term follow-up was performed to confirm prompt return to hyperglycemia, thereby ruling out residual function of native endocrine pancreas.
Clinically relevant immunosuppressive agents were used in both rat and NHP allogeneic transplant models (32–35). Rats received induction treatment with antilymphocyte serum (0.5 mL i.p. on day −3 [http://www.accurate.com.gr]) and mycophenolic acid (20 mg/kg/day starting on the day of transplant for 2 weeks then tapered by one-quarter of the dose every 2 days until day 20; Myfortic [https://www.novartis.com]) (36) combined with cytotoxic T-lymphocyte–associated protein-4 (CD152)–immunoglobulin fusion protein (CTLA4Ig) (10 mg/kg i.p. on days 0, 2, 4, 6, 8, and 10 and weekly thereafter; abatacept [Orencia] [http://www.bms.com]), adapted from Safley et al. (35). The NHP received anti-thymocyte (rabbit) globulin (10 mg/kg i.v. on days −1, 0, 2, and 4 from transplant; thymoglobulin; Sanofi), CTLA4Ig (20 mg/kg i.v. on days 0, 4, 14, 28, 56, and 75 and monthly thereafter at 10 mg/kg; belatacept [Nulojix] [http://www.bms.com]), and sirolimus (daily from day 2, aiming at trough levels of 8–12 ng/mL; rapamycin [http://www.lclabs.com]).
Blood samples were collected from indwelling JVC at baseline and after selected time points posttransplant. Insulin, C-peptide, leptin, interleukin (IL)-6, and chemokine (C-C motif) ligand 2 (CCL2) (formerly MCP-1) were measured using commercial multiplex kits (http://www.emdmillipore.com) and analyzed on a Luminex system. Levels of the rat acute-phase proteins α2-macroglobulin and haptoglobin were measured using specific ELISA kits (http://www.lifediagnostics.com) on a kinetic microplate reader (SoftMaxPro version 5; https://www.moleculardevices.com).
Tissue sections (4 µm thick) were stained with hematoxylin-eosin for morphologic assessment of the grafts. Masson trichrome staining (Chromaview, Richard-Allan Scientific [https://vwr.com]) was performed on selected grafts to reveal collagen (blue stain) or muscle fibers and cytoplasm (red stain) (25). Immunofluorescence was performed using specific antibodies to detect insulin (1:100; guinea pig anti-insulin [http://www.dako.com]), glucagon (GCG) (1:100; rabbit anti-glucagon [http://www.biogenex.com]), endothelium (1:20; rabbit anti-CD31 [http://www.abcam.com] or 1:50; von Willebrand factor [vWF], rabbit anti-vWf [http://www.emdmillipore.com]), smooth muscle actin (SMA) (1:50; rabbit anti-SMA [http://www.abcam.com]), and T cells (1:100; CD3, rabbit polyclonal anti-human [http://www.cellmarque.com]). Secondary antibodies used were goat anti–guinea pig Alexa Fluor 568 (1:200) and goat anti-rabbit Alexa Fluor 488 (1:200; Invitrogen [http://www.thermofisher.com]). Digital images were acquired using an SP5 inverted confocal microscope (http://www.leica.com) at the DRI Imaging Core Facility.
Scanning Electron Microscopy
Human plasma was obtained from volunteers who gave consent (IRB20091138). Human islets and plasma/thrombin clots with or without human islets were fixed in 2% glutaraldehyde in PBS (0.137 mol/L NaCl, 0.01 mol/L Na2HPO4, and 0.0027 mol/L KCl, pH 7.4) for ≥3 h and stored in fixative at 4°C. After three washes, samples were postfixed with 1% osmium tetroxide in PBS, dehydrated in ethanol, dried with hexamethyldisilazane, dispersed in plastic weigh boats, and outgassed overnight. Preparations were adhered by gentle tapping with an aluminum stub, covered with a carbon adhesive tab, and then coated with a 20-nm-thick layer of palladium in a plasma sputter coater and imaged at the UM Center for Advanced Microscopy using a field emission scanning electron microscope (FEI XL-30).
Data were analyzed using Excel (https://www.microsoft.com), SigmaPlot (http://www.sigmaplot.com), and Prism6 (http://www.graphpad.com). Shapiro-Wilk test was used to assess parametric data distribution. An unpaired t test was performed to compare experimental groups. Values shown are mean ± SEM, except where indicated. P values <0.05 were considered statistically significant.
Ultramicroscopic Structure of the Biologic Scaffold
Scanning electron microscopy revealed the intricate net of fibrin fibers obtained through the reaction triggered by rhT in human plasma (Fig. 2A). Human islet cell surface appeared smooth by ultramicroscopy (Fig. 2B). The clot induced by combining human plasma with rhT and human islets in vitro resulted in the development of an orthomorphic three-dimensional fibrin matrix trapping islet structures within the newly formed biologic scaffold (Fig. 2C). We reasoned that the induction of the plasma/thrombin reaction to create a microscopic, adherent fibrin scaffold around the implanted islets would be useful to promote islet graft adhesion on the surface of the omentum, preventing islet pelleting, and therefore aiding engraftment, neovascularization, and islet survival.
Intraomental Islets Transplanted Into Biologic Scaffolds Restore Normoglycemia in Diabetic Rats
We used a syngeneic rat islet transplant model. We previously demonstrated that streptozotocin diabetic recipients of 3,000 IEQ experienced reversal of diabetes after either intra- or extrahepatic transplantation (25). After intraomental transplantation of 17,338 ± 881 IEQ/kg, all animals (n = 7; 173.4 ± 91 g body wt) achieved normoglycemia within 2 days and maintained euglycemia during the follow-up period (Fig. 3A), even >200 days. Two animals underwent removal of the graft-bearing omentum on day 76 posttransplantation: one died after surgery and the other promptly become hyperglycemic (Fig. 3A). The rest of the recipients was followed for >200 days posttransplantation. IVGTT performed in selected animals 2 months after islet transplantation showed that transplanted islets cleared glucose within 75 min after receiving a glucose bolus in a fashion comparable with that of naïve animals (n = 3/group; AUC 17,851 ± 810 mg × min × dL−1 in naïve rats vs. 16,276 ± 857 mg × min × dL−1 in intraomental islet biologic scaffold recipients) (Fig. 3B). Furthermore, OGTT performed on transplanted animals at 11 and 26 weeks postimplantation confirmed comparable glucose clearance at both time points (n = 5; AUC 19,542 ± 1,735 mg × min × dL−1 at 11 weeks and 20,735 ± 785 mg × min × dL−1 at 26 weeks) (Fig. 3C). Histopathology of explanted grafts showed well-preserved islet cytoarchitecture (Fig. 3D–G), strong insulin immunostaining, and abundant intragraft vascularization (e.g., SMA); all features were compatible with adequate engraftment and corroborated the in vivo functional data.
Comparable Function of Intrahepatic and Intraomental Islets Transplanted Into Biologic Scaffolds
We compared the performance of syngeneic islets implanted within the intraomental biologic scaffold to that of intrahepatic grafts. Aliquots of 1,300 IEQ (∼8,200 IEQ/kg body wt [a “clinically relevant” mass]) from the same batch of islets were transplanted in parallel either within an intraomental biologic scaffold (n = 7; 160.3 ± 6.4 g body wt [8,122 ± 334 IEQ/kg]) (Fig. 4A) or in the intrahepatic site (n = 5; 155.4 ± 7.3 g body wt [8,380 ± 396 IEQ/kg]) (Fig. 4B). All recipients in both groups achieved euglycemia within 1 week and maintained good metabolic control during the 82-day (∼12 weeks) follow-up period. Omental graft removal resulted in a prompt return to hyperglycemia (n = 4) (Fig. 4A). At 5 (Fig. 4C) and 11 weeks posttransplant (Fig. 4D), OGTT showed comparable metabolic function in both transplant sites (AUC at 5 weeks, 18,393 ± 571 and 18,036 ± 598.5 mg × min × dL−1, and AUC at 11 weeks, 21,987 ± 2,580 and 21,149 ± 1,456 mg × min × dL−1, for intraomental biologic scaffold recipients or intrahepatic islet recipients, respectively) (Fig. 4C and D).
Lower Levels of Stress-Related Biomarkers in Recipients of Intraomental Islets Within a Biologic Scaffold
Selected biomarkers associated with islet distress and inflammation elicited by the transplantation procedure were evaluated. Blood samples were collected from JVC at different time points after transplantation. A spike in insulin and C-peptide levels, likely a result of insulin dumping from distressed islet cells (5,37,38), was observed 1 h posttransplant in both experimental groups. The insulin peak was significantly higher in the intrahepatic compared with the intraomental group (2.841 ± 0.338 vs. 1.405 ± 0.352 μg/mL, respectively; P = 0.018) (Fig. 5A), with comparable levels in both groups at subsequent time points (data not shown). No statistically significant differences were observed in C-peptide levels (2.565 ± 0.25 vs. 2.941 ± 0.303 μg/mL, respectively) (Fig. 5B).
Inflammatory biomarkers MCP-1/CCL2 (Fig. 5C) and IL-6 (Fig. 5D) showed comparable increases between experimental groups at 24 h, with undetectable values by 72 h posttransplant in both groups (not shown). Leptin levels were significantly higher at 24 h in the recipients of the intrahepatic compared with intraomental group (633 ± 31 vs. 483 ± 35 pg/mL, respectively; P = 0.013) (Fig. 5E). Acute-phase protein haptoglobin levels were comparable in both groups (Fig. 5F), while α2-macroglobulin levels were significantly higher in intrahepatic islet recipients versus the intraomental group at 24 h (280 ± 58 vs. 155 ± 26 pg/mL; one-tail t test: P < 0.03) (Fig. 5G).
Intraomental Biologic Scaffold Provides Adequate Engraftment of Low-Purity Islet Preparations
Clinical human islet preparations usually contain different degrees of impurities (e.g., exocrine tissue) that increase the final volume of transplanted tissue. We evaluated whether our intraomental biologic scaffold would be adequate for the implantation of clinically relevant, low-purity islet preparations. Implantation of 2,000 IEQ from either >95% pure (n = 3; 167.3 ± 1.5 g body wt [11,853 ± 109 IEQ/kg]) or 30% pure (n = 3; 170.3 ± 10.5 g body wt [11,771 ± 725 IEQ/kg]) syngeneic islet preparations led to rapid diabetes reversal (within 5 days) in all recipient rats (Fig. 6A). All animals maintained stable normoglycemia throughout the follow-up period and displayed comparable glucose clearance during OGTT (AUC: 17,776 ± 1,687 and 19,734 ± 1,997 mg × min × dL−1 for recipients of 90 and 30% pure preparations, respectively) (Fig. 6B). Surgical removal of the graft-bearing omentum was performed >100 days after transplantation. One of the recipients of 30% pure islets died after surgery, while all other animals in both groups showed prompt return to hyperglycemia, confirming the graft-dependent normoglycemia.
Intraomental Biologic Scaffold Provides Adequate Engraftment of Allogeneic Islets in Immunosuppressed Recipients
Suitability of the intraomental biologic scaffold to support islet engraftment under clinically relevant systemic immunosuppressive treatment (32–35) was evaluated in a fully MHC-mismatched allogeneic rat transplant combination. All four diabetic Lewis rat (RT1l) recipients of 3,000 IEQ WF islets (RT1u) achieved normoglycemia within 5 days and sustained graft function for up to 5 weeks posttransplantation under the transient systemic immunosuppression protocol used, when graft rejection coincided with return to a hyperglycemic state (Fig. 7).
Intraomental Islet Transplant in a Biologic Scaffold Engrafts in a Preclinical Model
We also tested the effect of the biologic scaffold in a clinically relevant preclinical model of allogeneic islet transplantation in a diabetic cynomolgus monkey. Before transplantation, the animal required ∼4–5 IU/kg/day exogenous insulin with plasma C-peptide <0.05 ng/mL (Fig. 8). An islet mass of ∼48,700 IEQ (∼150 μL total islet graft volume) equivalent to 9,347 IEQ/kg was implanted. The transplant procedure and postoperative clinical outcome were uneventful, with standard recovery from surgery. After the first few weeks posttransplant, improvement of FBG and PBG was observed, requiring progressive reduction of exogenous insulin (Fig. 8A). Positive fasting C-peptide levels (Fig. 8B) were observed immediately posttransplant and throughout follow-up. The animal subsequently expired on postoperative day (POD) 49 owing to technical complications unrelated to the engraftment site. Histopathologic assessment of the explanted graft demonstrated well-preserved islet morphology (Fig. 8C) with immunoreactivity for the endocrine markers insulin and glucagon (Fig. 8D), some degree of peri-insular lymphocyte infiltrate (CD3) (Fig. 8E), and abundant intra- and extrainsular vascular structures (SMA [Fig. 8F] and vWF [Fig. 8G]).
Our study was aimed at developing a clinically applicable protocol for extrahepatic transplantation of pancreatic islets. Over the past 20 years, the omentum has been studied as a possible islet implantation site in different animal models, after the initial description by Yasunami et al. (39) using rat isografts and later reports in large animals (40–42). Owing to portal venous drainage, the omentum may attain more physiologic metabolic responses compared with intrahepatic and other islet transplantation sites that were associated with hyperinsulinemia, insulin resistance, and impairment of insulin action in animal models (20,21,23). Human islet cell implants survived better in the omentum than intrahepatically in immunodeficient rats, and their engraftment correlated positively with number and purity of implanted cells (43). Perinatal porcine islet cells displayed comparable growth of the β-cell volume over time in the omentum and kidney subcapsular space, the former leading to higher insulin reserves and an increased pool of proliferating cells (44). These data reinforce the feasibility of the omentum as a potentially favorable site for the implantation of insulin-producing cell products in clinical protocols.
From the clinical translational perspective, the omentum can be accessed using minimally invasive surgical techniques (e.g., minilaparotomy or laparoscopy), and it may allow implementation of bioengineering approaches to enhance islet engraftment, survival, and development of strategies for the reduction and eventual elimination of chronic systemic immunosuppression of the recipients (14,22,45). We evaluated the potency of islets implanted onto the omentum using an autologous resorbable biologic scaffold to promote islet adherence onto its surface using only clinical grade reagents (e.g., rhT). The clinical safety profile of rhT has been established to promote hemostasis during surgical procedures (46). We reasoned that applying islets suspended in autologous plasma on the surface of the omentum would accommodate relatively large islet volumes while minimizing pelleting. A similar approach based on three-dimensional islet-plasma constructs prepared ex vivo and then rolled up within the greater omentum was described in pancreatectomized dogs (47).
Our in vitro results showed that addition of rhT to human islets resuspended in human plasma generates a complex, orthomorphic fibrin matrix embedding the islets. Our in vivo studies demonstrate that islets transplanted in the in situ–generated biologic scaffold onto the omentum of diabetic animals engraft and function long-term. Normalization of nonfasting glycemic values and responses during metabolic challenges were reproducibly achieved in recipients of syngeneic islets in an intraomental biologic scaffold. Histopathology showed preserved islet cytoarchitecture in the presence of rich intrainsular vascular structures and lack of fibrosis in both rodent and NHP models. Moreover, when adequate islet numbers were implanted in the rat model (i.e., >1,300 IEQ; ∼8,200/kg body wt), there was comparable potency between intraomental and intrahepatic transplants. However, a higher proportion of intrahepatic islet recipients achieved metabolic control when a marginal (though not clinically relevant) syngeneic rat islet mass of 450 IEQ, representing ∼2,700/kg body wt, was implanted (data not shown). It is noteworthy that 5,000 IEQ/kg body wt is currently the minimum requirement for clinical intrahepatic islet transplantation, and insulin independence is generally attained when >12,000 IEQ/kg are implanted (1).
Serum levels of insulin and C-peptide, surrogate biomarkers of acute β-cell distress and death associated with the implantation procedure (5,37,38), were increased 1 h postimplant, with higher levels in recipients of intrahepatic versus intraomental islets. Perhaps the lower intraomental levels are due, at least in part, to the lack of shear forces and IBMIR in this site (4,6). While the kinetics for appearance of the inflammatory markers IL-6, MCP-1/CCL2, and haptoglobin were comparable, α2-macroglobulin levels were higher 24 h after intrahepatic versus intraomental transplantation. Notably, the pleomorphic plasma protein α2-macroglobulin interfaces with the coagulation system and is an acute-phase protein (48). This result may be due to hepatic tissue responses after islet embolization in the portal system (i.e., Kupffer cell activation and in the context of thrombi). Levels of leptin, a mediator of innate immunity through multiple proinflammatory effects (49), increased in both groups but were higher in the intrahepatic compared with the intraomental islet recipients, reaching statistical significance at the 24-h time point. Collectively, these data suggest a lower degree of inflammation generated after intraomental islet implantation in the biologic scaffold compared with the liver.
Antithrombin agents have been proposed to reduce IBMIR and promote intrahepatic islet engraftment (50). Our data indicate that thrombin per se is not detrimental to islet engraftment when used in an extravascular (extrahepatic) site to induce a resorbable matrix in vivo. This is likely due to the absence of the plethora of proinflammatory events associated with intravascular thrombosis in the hepatic sinusoids, including transplant microenvironment activation (platelets, leukocytes, and endothelial cells), that lead to islet hypoxia and loss of functional islet mass.
Human islet preparations generally include low-purity fractions of the final cellular product to achieve adequate endocrine cell mass for transplantation. However, the final volume of clinical human islet preparations implanted is generally kept <10 mL to reduce the risk of portal vein hypertension after embolization in the liver sinusoids. The net effect of the inclusion of exocrine fractions in the islet transplant preparation remains to be determined (51). Exocrine tissue may be detrimental to islet graft outcome because of competition for nutrients and oxygen in the transplant site, contribution to microenvironment activation, and increased antigenic mass transplanted. Conversely, exocrine tissue may comprise critical cellular precursors that promote engraftment, tissue remodeling, and endocrine cell plasticity, leading to long-term function after transplantation (52,53). In light of the promising long-term results of autologous intrahepatic human islet grafts (not or minimally purified) (54), development of extrahepatic implantation sites that accommodate impure islet preparations represents a desirable goal for clinical islet transplantation (14,15,55). In this study, transplantation of islet preparations with low purity (30% endocrine) resulted in stable metabolic control that was comparable with that of pure preparations (>95% endocrine) transplanted into the biologic intraomental scaffold.
Our preclinical studies of islet transplantation support the feasibility of intraomental transplantation of islets using the described in situ–generated biologic scaffold. Using both rat and NHP models, we demonstrated that allogeneic islets implanted in the intraomental biologic scaffold under clinically relevant immunosuppression (32) can engraft and improve glucose control and that this procedure may be feasible and effective in human subjects. The implantation procedure that we have optimized allows for distribution of the grafted tissue on the large omental surface and the creation of a thin adherent biologic scaffold in situ with minimal manipulation, avoiding islet pelleting (even in the case of low-purity cell products). Folding of an omental flap on the scaffold creates a double outer omental layer containing the graft, increasing surface contact (for nutrient diffusion and subsequent neovascularization), and protecting the islets from shear forces (peristalsis and diaphragm excursions) in the peritoneal cavity. The use of only two components (namely, the patient’s own plasma and rhT) to generate a resorbable biologic scaffold and the simplicity of the implantation technique make our approach easy to implement and clinically translatable. Furthermore, it may represent an initial step toward engineering the transplant site to enhance β-cell replacement therapies for insulin-requiring diabetes (14,22,45). A phase I/II pilot clinical trial is currently ongoing at our center to evaluate the safety and efficacy of transplanting single-donor allogeneic islets in biologic intraomental scaffolds under conventional immunosuppression in people with brittle T1D.
Acknowledgments. The authors thank Paul Latta (Converge Biotech); the faculty and staff of the DRI’s Cell Transplant Center, particularly Dr. Rodolfo Alejandro and Dr. Luca Inverardi; Christian La Sala (DRI Preclinical Cell Processing and Translational Models Program); Dr. Joel Szust, Alejandro Tamayo-Garcia, Yelena Gadea, and Elsie Zahr-Akrawi (DRI Translational Core); Kevin Johnson (DRI Histology Lab); Dr. Patricia L. Blackwelder (UM Center for Advanced Microscopy); Dr. Marcia Boulina (DRI Imaging Core); Dr. Elina Linetsky (DRI cGMP Human Cell Processing Core); Waldo Diaz, James Geary, and Reiner Rodriguez-Lopez for excellent NHP care; and Alexander Rabassa, Ena Poumian-Ruiz, and Melissa Willman for assistance with NHP islet isolation and preliminary in vitro testing. The authors give special thanks to the UM Institutional Animal Care and Use Committee, UM Office of Environmental Health and Safety, and Division of Veterinary Resources for valuable support provided.
Funding. This study was partially supported by the Diabetes Research Institute Foundation (www.diabetesresearch.org), by the Leona M. and Harry B. Helmsley Charitable Trust, and by JDRF International (17-2012-361). The project was part of A.P.’s Master of Science in Clinical and Translational Investigation training, a program supported by the UM Clinical and Translational Science Institute, from the National Center for Advancing Translational Sciences and the National Institute on Minority Health and Health Disparities (1UL1TR000460).
The contents of this article are solely the responsibility of the authors and do not necessarily represent the official views of the funding agencies. The opinions expressed in this article are the authors’ own and do not reflect the view of the National Institutes of Health, the Department of Health and Human Services, or the U.S. government.
Duality of Interest. UM and R.D.M., N.S.K., C.R., and A.P. hold, but do not receive royalties for, intellectual property used in this study and are also equity owners in Converge Biotech. No other potential conflicts of interest relevant to this article were reported.
Author Contributions. D.M.B., C.R., and A.P. developed the concept. D.M.B., R.D.M., C.R., and A.P. conceived and designed the studies, performed experiments, optimized protocols, analyzed data, and wrote the manuscript. C.F., N.M.K., and N.S.K. performed experiments, analyzed data, provided intellectual input, and reviewed the manuscript. U.U. and J.G. performed experiments, analyzed data, and reviewed the manuscript. A.J.M. and D.M.A. provided intellectual feedback and reviewed the manuscript. C.R. and A.P. are the guarantors of this work and, as such, had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.
Prior Presentation. Parts of this study were presented in abstract form at the 12th Congress of the Cell Transplant Society, Milan, Italy, 7–11 July 2013, and at the 75th Scientific Sessions of the American Diabetes Association, Boston, MA, 5–9 June 2015.
D.M.B., R.D.M., C.R., and A.P. equally contributed.
Clinical trial reg. no. NCT02213003, clinicaltrials.gov.
A.P. is currently affiliated with the Center for Scientific Review, National Institutes of Health, Bethesda, MD.
- Received November 4, 2015.
- Accepted February 17, 2016.
- © 2016 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.