Pre-treatment of porcine pulmonary xenograft with desmopressin: a novel strategy to attenuate platelet activation and systemic intravascular coagulation in an ex-vivo model of swine-to-human pulmonary xenotransplantation

Abstract: Background: Von Willebrand factor (vWF) has been proposed as a major contributor to the development of coagulopathy in pulmonary xenotransplantation. Pretreatment of donor swine with 1‐deamino‐8‐d ‐arginine vasopressin (DDAVP), an analog of vasopressin, can reduce the content of vWF in pulmonary xenografts. Here, we investigate the effects of DDAVP pre‐treatment in an ex‐vivo perfusion model of pulmonary xenotransplantation. Methods: We set up and performed the ex‐vivo perfusion using porcine pulmonary accessory lobes and fresh human whole blood (n = 12). Half of the donor swine were given 3 μg/kg DDAVP intravenously for 3 days before ex‐vivo perfusion (DDAVP group) and half of them were left untreated (control group). The porcine lung was perfused with fresh blood for 1 h and changes in the following parameters were monitored: pulmonary arterial pressure, pulmonary vascular resistance, blood cell counts, fibrinogen, antithrombin, platelet factor 4, D‐dimer, C3a, C4d, and xenoreactive IgM. The release of Galα1‐3Gal xenoantigen (αGal) from porcine lung which had been perfused and retained for 30 min with human blood was assessed by enzyme‐linked immunosorbent assay using αGal‐binding lectin. Results: Both DDAVP and control groups showed typical findings of immediate pulmonary dysfunction: an increase of pulmonary vascular resistance and sequestration of leukocytes and platelets after ex‐vivo perfusion. However, in the DDAVP group, the increase of platelet factor 4, C3a, and C4d after perfusion was attenuated compared to that in the control group. The release of αGal after blood retention was significantly lower in the DDAVP group than that of the control group. Conclusion: Pre‐infusion of DDAVP to the donor swine was beneficial in attenuating platelet activation as well as complement/coagulation activation. These effects of DDAVP are likely to relate to the reduction of porcine vWF content in the xenograft. Therefore, the modulation of vWF secretion in donor lungs could be an additional therapeutic way to reduce systemic coagulopathy in pulmonary xenotransplantation.     

The Role of Antibodies and Von Willebrand Factor in Discordant Pulmonary Xenotransplantation

Pulmonary xenotransplantation is one potential solution to the paucity of donors but is currently limited by rapid failure of the graft. Unlike cardiac and renal xenotransplants, pulmonary xenografts release large quantities of swine von Willebrand factor (vWF). Swine vWF binds xenoreactive antibodies and is capable of activating primate platelets. The contribution of swine vWF to lung xenograft dysfunction is not entirely clear. To probe the role vWF plays in xenograft dysfunction, we traced the fate of xenoantibodies in vWF+ and von Willebrand factor-deficient (vWFD) swine lungs. These studies showed that the vast majority of xenoantibodies bind the vWF released from the vWF+ swine lung, and thus do not remain bound on lung endothelium. The vWF complexed to xenoantibody remained capable of aggregating primate platelets. With this information, we performed swine-to-baboon lung transplants using vWF+ and vWFD donors. Without vWF present to complex xenoantibodies, a picture of hyperacute rejection more typical of heart and kidney xenografts, with antibody deposition along the graft endothelium, interstitial hemorrhage, and edema occurred. These findings suggest that porcine vWF plays a major role in the pathogenesis of pulmonary xenograft dysfunction, and suggests promising strategies to treat lung xenograft dysfunction.     

Non-anti-Gal alpha1-3Gal antibody mechanisms are sufficient to cause hyperacute lung dysfunction in pulmonary xenotransplantation

BACKGROUND: Hyperacute lung dysfunction, which is always associated with pulmonary pig-to-primate xenotransplantation is not well understood. The mechanisms associated with its occurrence seem to differ from mechanisms involved in hyperacute xenograft rejection seen in porcine hearts or kidneys transplanted into primates. To determine the contribution of anti-Gal alpha1-3Gal antibodies (alphaGAb) in such a process, we performed a set of orthotopic pig lung transplants into baboons depleted of alphaGAb and compared graft function and survival with those receiving only immunosuppression. STUDY DESIGN: Pigs expressing human membrane cofactor protein served as donors. All baboons received triple immunosuppressive therapy. Depletion of alphaGAb in the experimental group (n = 4) was done by way of immunoadsorption using immunoaffinity membranes. Controls (n = 4) did not undergo immunoadsorption. Orthotopic lung transplants were performed through a left thoracotomy. Main pulmonary artery blood flow and pressure, left pulmonary artery blood flow, and left atrial pressure were recorded. RESULTS: At 1 hour after reperfusion, pulmonary artery graft flows and pulmonary vascular resistances (PVR) were better in animals depleted of alphaGAb than in controls (605 +/- 325.2 mL/min versus 230 +/- 21 mL/min; 27.1 +/- 41.3 mmHg/L/min versus 63 +/- 1 mmHg/L/min). But at 3 hours after reperfusion average graft flows in baboons depleted of alphaGAb had decreased to 277.6 +/- 302.2 mL/min and PVRs had increased 58.3 +/- 42.0 mmHg/L/min. On the other hand, controls maintained stable flows and PVRs (223 +/- 23 mL/min; 61 +/- 3 mmHg/L/min). Survival was ultimately better in control baboons when compared with alphaGAb depleted ones (12.2 +/- 3.3 h versus 4.4 +/- 3.2 h). CONCLUSION: Unlike heart and kidney xenograft transplants, hyperacute lung xenograft dysfunction seems to be mediated by factors other than alphaGAb.     

Pre-treatment of donor with 1-deamino-8-d-arginine vasopressin could alleviate early failure of porcine xenograft in a cobra venom factor treated canine recipient.

OBJECTIVE: Unlike cardiac or renal xenotransplants, the depletion of complement using cobra venom factor (CVF) does not improve pulmonary xenograft survival. Several cases suggest that the swine von Willebrand factor (vWF) may play a major role in presenting a different pathogenesis of pulmonary xenograft dysfunction from other organs. To evaluate the role of vWF and the complement system in mediating hyperacute vascular injury of pulmonary xenografts and elucidate pathogenesis of the injury, we performed swine-to-canine orthotropic single lung xenotransplantation after pre-treatment of 1-deamino-8-d-arginine vasopressin (DDAVP) and CVF. METHODS: We set up three groups for lung xenotransplantation: group I served as the control group; group II, recipients pre-treated with CVF; group III, donors pre-treated with DDAVP (9 mg/kg, 3 days)/recipients pre-treated with CVF (60 u/kg). Hemodynamic data, coagulation and complement system parameters, and grafted lung pathologies were examined serially for 3h after transplantation. RESULTS: DDAVP infusion reduced the vWF content in swine lung tissue in vivo (7.7+/-2.4 AU/mg vs 16.0+/-5.6 AU/mg, P < 0.0001). Infusion of CVF 24 h prior to transplantation effectively depleted the recipient's serum C3 and complement hemolytic activity below the detectable range. Regardless of the use of CVF, both groups I and II transplanted with unmodified grafts showed an immediate drop in leukocytes and platelet counts after transplantation. However, in group III, in recipients transplanted with DDAVP pre-treated swine lung, the platelet count did not decrease after transplantation (P = 0.0295). The decrease of plasma antithrombin and fibrinogen tended to be attenuated in group III. Light microscopic examination revealed extensive vascular thromboses in both capillary and larger vessels, as well as early pulmonary parenchymal damage in groups I and II, but were rarely observed in group III. CONCLUSIONS: Complement inhibition alone was not enough to alleviate intravascular thrombosis, the main pathology in pulmonary xenotransplantation. Pre-infusion of DDAVP to the donor animal was effective in preventing platelet sequestration and attenuated intravascular thrombosis. It is suggested that the strategies targeting vWF would be promising for successful pulmonary xenotransplantation.     

Evidence for polyreactive xenoreactive antibodies in the repertoire of human anti-swine antibodies: the 'next' humoral barrier to xenotransplantation?

The xenoreactive nature of anti-Galalpha1-3Gal antibodies, and to a lesser extent, polyreactive antibodies, has been characterized by a number of investigators. With the advent of therapies that avoid hyperacute xenograft rejection due to anti-Galalpha1-3Gal antibodies coupled with the possible development of Galalpha1-3Gal deficient swine, the Galalpha1-3Gal antigen may soon cease to be a barrier to xenotransplantation. With this in mind, the potential xenoreactive nature of polyreactive antibodies was investigated using several approaches. The levels of polyreactive antibodies from the serum of newborn (n = 2) and adult (n = 4) baboons undergoing pulmonary xenotransplantation were evaluated. Depletion of 95% and 94% of total serum IgM, without any decrease in albumin levels, was observed in the newborn baboons. This finding indicates that the IgM present at birth and germ line polyreactive IgM was adsorbed by the xenografts. The depletion of polyreactive antibodies (43-83% reduction of anti-DNP IgM) from adult baboons was also observed following pulmonary xenotransplantation or immunoadsorption therapy plus pulmonary xenotransplantation. Additional experiments using human cord serum indicated that most human polyreactive IgM were adsorbed by pig lung homogenate and that the human polyreactive IgM bound approximately two-fold more to immobilized pig lung antigens than to immobilized human lung antigens. These findings indicate that germline polyreactive antibodies are, for the most part, xenoreactive. These data suggest that polyreactive antibodies, although autoreactive, may be more xenoreactive than autoreactive.     

Lung xenogenic injury: does anticoagulation help?

The shortage of human organ donors remains a major limitation to the field of transplantation [1], and can potentially be solved using xenografts. During the past decade, many advances have been made to address the major initial immunological obstacle to “discordant” pig‐to‐human solid organ transplantation: hyperacute rejection (HAR). As organs from unmodified pigs were evaluated in animal models, HAR was found to be primarily a consequence of the recipient's preformed anti‐pig antibodies binding on porcine vascular endothelial cells leading to subsequent complement activation, thrombosis and graft failure [2]. This process occurs within minutes to hours of human blood perfusion in porcine organs. Since the carbohydrate structure Galactose‐α(1,3‐Galactose (Gal) is recognized by over 80% of anti‐pig antibodies found in man, genetically modified galactosyl transferase knock‐out (GalTKO) pig organs have been developed [3,4]. Endothelium and parenchymal cells from GalTKO animals lack the Galα1,3Gal epitope. As predicted, heart and kidney transplant studies in baboons showed that the GalTKO phenotype is associated with decreased antibody binding, reduced activation of the complement cascade and prolonged graft survival [5–8]. However, delayed xenograft rejection, consumptive coagulopathy and microangiopathy limit long‐term outcomes. Xenogenic lungs are even more sensitive to xenogenic injury [9, 10], even with additional expression of complement regulatory protein human CD46 [Burdorf et al]. Immunohistology and biochemical evidence and work by others implicated inflammation and coagulation cascade activation as residual xenogenic injury pathways. To determine the role of these pathways in lung xenogenic injury, our group is evaluating new transgenic pigs [11] and various pharmacologic approaches. New transgenes include human thrombomodulin (hTM), endothelial protein C receptor (EPCR) and ectonucleoside triphosphate diphosphohydrolase‐1 (CD39). Pharmacologic interventions consist in targeting platelet receptors (GPIb, GPIIbIIIa), thrombin (hirulog) and adding exogenous activated protein C to perfused human blood and administering desmopressin to lung donor pigs. The differential effects of these interventions on lung physiological parameters, platelet and coagulation activation will be summarized. Future work will place emphasis on combined targeting of these pathways. Acknowledgments: Funded in part by NIH (IU19A1090959, 1U01AI066335) and by gifts from Revivicor and United Therapeutics. References 1. Cooper DKC. Xenografting: how great is the clinical need? Xeno 1993; 1: 25–26. 2. Pierson RNIII. Antibody‐mediated xenograft injury: mechanisms and protective strategies. Transpl Immunol 2009; 21: 65–69. 3. Phelps CJ, Koike C, Vaught TD et al.Production of alpha 1,3‐galactosyltransferase‐deficient pigs. Science 2003; 299: 411–414. 4. Kolber‐ Simonds D, Lail L, Watt SR et al. Production of alpha‐1,3‐galactosyltransferase null pigs by means of nuclear transfer with fibroblasts bearing loss of heterozygosity mutations. Proc Natl Acad Sci U S A 2004; 101: 7335–7340. 5. Tseng YL, Kuwaki K, Dor FJ et al. alpha1,3‐Galactosyltransferase gene‐knockout pig heart transplantation in baboons with survival approaching 6 months. Transplantation 2005; 80: 1493–1500. 6. Kuwaki K, Tseng YL, Dor FJet al. Heart transplantation in baboons using alpha1,3‐galactosyltransferase gene‐knockout pigs as donors: initial experience. Nat Med 2005; 11: 29–31. 7. Yamada K, Yazawa K, Shimizu Aet al. Marked prolongation of porcine renal xenograft survival in baboons through the use of alpha1,3‐galactosyltransferase gene‐knockout donors and the cotransplantation of vascularized thymic tissue. Nat Med 2005; 11: 32–34. 8. Mohiuddin MM, Corcoran PC, Singh AK, et al. B‐cell depletion extends the survival of GTKO.hCD46Tg pig heart xenografts in baboons for up to 8 months. Am J Transplant. 2012; 12:763–71. 9. Nguyen BN, Azimzadeh AM, Zhang T, et al. Life‐supporting function of genetically modified swine lungs in baboons. J Thorac Cardiovasc Surg 2007; 133: 1354–1363. 10. Nguyen BN, Azimzadeh AM, Schroeder C et al. Absence of Gal epitope prolongs survival of swine lungs in an ex vivo model of hyperacute rejection. Xenotransplantation. 2011; 18:94–107. 11. Cooper DK, Ekser B, Burlak C et al. Clinical lung xenotransplantation – what donor genetic modifications may be necessary? Xenotransplantation. 2012; 19:144–58.     

Cardiac xenotransplantation: progress toward the clinic

BACKGROUND: Animal organs could satisfy the demand for solid organ transplants, which currently exceeds the limited human donor supply. Hyperacute rejection, the initial immune barrier to successful xenotransplantation, has been overcome with pig donors transgenic for human complement regulatory proteins. Delayed xenograft rejection, thought to be mediated by anti-pig antibodies predominantly to Gal antigens, is currently regarded as the major barrier to successful xenotransplantation. A median graft survival of 90 days in the life-supporting position is considered a reasonable initial standard for consideration of entry to the clinic. METHODS: A series of 10 heterotopic heart transplants from CD46 transgenic pigs to baboons was completed. Immunosuppression consisted of splenectomy, Rituximab (Anti-CD20), tacrolimus, sirolimus, corticosteroids, and TPC. Thymoglobulin (Rabbit Anti-Thymocyte Globulin) was used to treat putative rejection episodes. RESULTS: Median graft survival was 76 days (range 56-113 days, n = 9). Only three grafts were lost to rejection. The remaining grafts lost were due to recipient mortality with baboon cytomegalovirus (BCMV) being the major cause (n = 4). No cellular infiltrates were present as a manifestation of rejection. Three hearts showed chronic graft vasculopathy. CONCLUSIONS: The median survival of 76 days in this group of heterotopic porcine-to-baboon cardiac xenografts represents a major advance over the median 27-day survival reported in the literature. Cellular rejection may not constitute a direct major barrier to xenotransplantation. A median survival of 90 days may be achievable with better control of BCMV infection. If further studies in the orthotopic position replicate these outcomes, criteria considered appropriate for clinical application of cardiac xenotransplantation would be approached.     

Depletion of pulmonary intravascular macrophages prevents hyperacute pulmonary xenograft dysfunction

BACKGROUND: Recent years have brought dramatic progress in the field of xenotransplantation, with the development of transgenic swine and various other means of overcoming the rejection mediated by xenoreactive antibodies. Although progress has been rapid with kidney and heart xenografts, progress with pulmonary xenografts has lagged behind. Recent findings have suggested that donor pulmonary intravascular macrophages may play a critical role in the hyperacute dysfunction of pulmonary xenografts. METHODS: The function of pulmonary xenografts from pigs depleted of pulmonary intravascular macrophages was compared with the function of xenografts from normal pigs. RESULTS: Pulmonary xenografts from pigs from which pulmonary intravascular macrophages were depleted survived (23.5+/-0.9 hours) about five times longer than normal (macrophage sufficient) xenografts (4.4+/-1.41 hours) (P< 0.0001). At 21 hours post-reperfusion, the left pulmonary arterial flow was 225.0+/-34 ml/min in lungs depleted of pulmonary intravascular macrophages, whereas all normal xenografts had failed. CONCLUSIONS: These findings indicate that donor macrophages play a critical role in pulmonary xenograft dysfunction. This finding has broad implications for xenotransplantation, suggesting that porcine macrophages might pose a barrier to the engraftment and function of a variety of porcine organ xenografts.     

Vascularized thymic lobe transplantation in a pig-to-baboon model: a novel strategy for xenogeneic tolerance induction and T-cell reconstitution

BACKGROUND: This laboratory has previously demonstrated the induction of allogeneic tolerance by vascularized thymic lobe (VTL) transplantation in miniature swine. We report here our initial attempt to induce tolerance by VTL transplantation in the clinically relevant, discordant, pig-to-baboon model of xenotransplantation. METHODS: Six baboons received xenografts of hDAF VTLs. Four of these baboons also received omental thymic tissue implants. All recipients were treated with an immunosuppressive conditioning regimen that included thymectomy, splenectomy, extracorporeal immunoadsorption of anti-alpha Gal antibodies, and T-cell depletion. Two control baboons received sham operations, of which one also received 5x10 hDAF porcine thymocytes/kg intravenously. RESULTS: Transplanted VTL grafts supported early thymopoiesis of recipient-type immature thymocytes, and facilitated engraftment of nonvascularized thymic omental implants. Recipients of the VTL grafts demonstrated donor-specific unresponsiveness in MLR assays, development of peripheral CD45RAhigh/CD4 double positive (DP) cells, and positive cytokeratin staining of thymic stroma in the grafts for 2 months following xenotransplantation. The control baboons did not show these markers of thymic reconstitution. The eventual return of Gal natural antibodies led to the destruction of graft epithelial cells and the rejection of all VTL grafts by 3 months posttransplantation. CONCLUSIONS: VTL transplantation from hDAF swine to baboons induced early thymopoiesis in the recipients and donor-specific cellular unresponsiveness in vitro. When coupled with additional strategies aimed at silencing humoral rejection, VTL transplantation may significantly prolong xenograft survival and result in long-term tolerance.     

Non-anti-Galα1-3Gal antibody mechanisms are sufficient to cause hyperacute lung dysfunction in pulmonary xenotransplantation

BACKGROUND:Hyperacute lung dysfunction, which is always associated with pulmonary pig-to-primate xenotransplantation is not well understood. The mechanisms associated with its occurrence seem to differ from mechanisms involved in hyperacute xenograft rejection seen in porcine hearts or kidneys transplanted into primates. To determine the contribution of anti-Galα1-3Gal antibodies (αGAb) in such a process, we performed a set of orthotopic pig lung transplants into baboons depleted of αGAb and compared graft function and survival with those receiving only immunosuppression.STUDY DESIGN:Pigs expressing human membrane cofactor protein served as donors. All baboons received triple immunosuppressive therapy. Depletion of αGAb in the experimental group (n = 4) was done by way of immunoadsorption using immunoaffinity membranes. Controls (n = 4) did not undergo immunoadsorption. Orthotopic lung transplants were performed through a left thoracotomy. Main pulmonary artery blood flow and pressure, left pulmonary artery blood flow, and left atrial pressure were recorded.RESULTS:At 1 hour after reperfusion, pulmonary artery graft flows and pulmonary vascular resistances (PVR) were better in animals depleted of αGAb than in controls (605 ± 325.2 mL/min versus 230 ± 21 mL/min; 27.1 ± 41.3 mmHg/L/min versus 63 ± 1 mmHg/L/min). But at 3 hours after reperfusion average graft flows in baboons depleted of αGAb had decreased to 277.6 ± 302.2 mL/min and PVRs had increased 58.3 ± 42.0 mmHg/L/min. On the other hand, controls maintained stable flows and PVRs (223 ± 23 mL/min; 61 ± 3 mmHg/L/min). Survival was ultimately better in control baboons when compared with αGab depleted ones (12.2 ± 3.3 h versus 4.4 ± 3.2 h).CONCLUSION:Unlike heart and kidney xenograft transplants, hyperacute lung xenograft dysfunction seems to be mediated by factors other than αGAb.     

Elicited non-anti-alphaGAL antibodies may cause acute humoral rejection of hDAF pig organs transplanted in baboons

The combination of immunosuppression and GAS 914, a polylysine containing alphaGal trisaccharide type 2 (TRI 2), has been associated with the prevention of acute humoral xenograft rejection (AHXR) in human decay accelerating factor (hDAF) pig-to-baboon xenotransplants. The aim of this study was to investigate the role of immunosuppression and GAS 914 to neutralize xenoantibodies before and after xenotransplantation. Eight baboons underwent heteropic heart xenotransplantation with hDAF transgenic pig organs, receiving GAS 914 before and after transplantation. Six baboons (Group A) were treated with an immunosuppression protocol that included cyclophosphamide (CyP), Neoral, ERL, and steroids. The other 2 baboons (Group B) were treated with the same immunosuppression but with a 50% reduction in the doses of CyP. No xenograft from Group A underwent acute humoral xenograft (median survival, 27 days), whereas the 2 in Group B experienced rejection (median survival, 6 days). GAS 914 depleted both immunoglobulin (Ig)M and IgG anti-alphaGAL disaccharide (DI), trisaccharide type 2 (TRI 2), and trisaccharide type 6 (TRI 6), before and after transplantation in Groups A and B. However, cytotoxic antibodies with other anti-pig specificities were elicited by the xenografts in Group B leading to AHXR.     

Xenogeneic thymokidney and thymic tissue transplantation in a pig-to-baboon model: I. Evidence for pig-specific T-cell unresponsiveness

BACKGROUND: The potential of xenotransplantation for clinical application will require overcoming barriers of humoral and cellular rejection, through strategies using immune suppression or tolerance induction. This laboratory has previously reported the induction of tolerance in the discordant xenogeneic model of pig-to-rodent thymic transplantation. We also have described a miniature swine model of fully mismatched allogeneic composite vascularized thymokidney transplantation that induced transplantation tolerance. We tested a combination of these approaches in a clinically relevant pig-to-primate model of xenotransplantation. METHODS: Composite thymokidney grafts were prepared 40 to 80 days before transplantation by the autologous implantation of thymic tissue under the renal capsule of human decay-accelerating factor transgenic swine. Baboons received xenotransplants of both human decay-accelerating factor composite thymokidneys and omental implants of thymic tissue. Recipients were treated with an immunosuppressive-conditioning regimen including thymectomy or thymic irradiation, extracorporeal immunoadsorption of anti-alphaGal antibodies and T-cell depletion. Recipients were followed for indicators of xenograft rejection, T-cell depletion and reconstitution, anti-alphaGal antibody levels, and mixed lymphocyte responses. Immunologic responses were studied in those animals that survived for more than 3 weeks. RESULTS: Thymokidney xenografts survived for up to 30 days, with evidence of viable thymic epithelium and Hassall's corpuscles under the renal capsule and in the omental implants, and with evidence of few host lymphocytes. Three animals demonstrated donor-specific unresponsiveness, while maintaining normal alloresponses, in mixed-lymphocyte-response assays performed after immunosuppression had been stopped. Rejected grafts demonstrated humoral damage without evidence of cellular infiltrates. After graftectomy, one animal maintained donor-specific cellular unresponsiveness and stable anti-alphaGal antibody levels for more than 2 months. CONCLUSIONS: We concluded that composite thymokidney and thymic-tissue xenotransplantation from swine to baboons can induce donor-specific cellular unresponsiveness and stable anti-alphaGal antibody levels, suggesting avoidance of sensitization after xenotransplantation. The presence of viable donor-swine thymic epithelium could have a role in the development of donor-specific T-cell tolerance. Further strategies to address humoral rejection could prolong graft survival and result in long-term tolerance to xenografts.     

Up to 9-day survival and control of thrombocytopenia following alpha1,3-galactosyl transferase knockout swine liver xenotransplantation in baboons

Kim K, Schuetz C, Elias N, Veillette GR, Wamala I, Varma M, Smith RN, Robson SC, Cosimi AB, Sachs DH, Hertl M. Up to 9‐day survival and control of thrombocytopenia following GalT‐KO swine liver xenotransplantation in baboons. Xenotransplantation 2012; 19: 256–264.. © 2012 John Wiley & Sons A/S. Abstract: Background:  With standard miniature swine donors, survivals of only 3 days have been achieved in primate liver‐transplant recipients. The recent production of alpha1,3‐galactosyl transferase knockout (GalT‐KO) miniature swine has made it possible to evaluate xenotransplantation of pig organs in clinically relevant pig‐to‐non‐human primate models in the absence of the effects of natural anti‐Gal antibodies. We are reporting our results using GalT‐KO liver grafts. Methods:  We performed GalT‐KO liver transplants in baboons using an immunosuppressive regimen previously used by our group in xeno heart and kidney transplantation. Post‐operative liver function was assessed by laboratory function tests, coagulation parameters and histology. Results:  In two hepatectomized recipients of GalT‐KO grafts, post‐transplant liver function returned rapidly to normal. Over the first few days, the synthetic products of the donor swine graft appeared to replace those of the baboon. The first recipient survived for 6 days and showed no histopathological evidence of rejection at the time of death from uncontrolled bleeding, probably caused by transfusion‐refractory thrombocytopenia. Amicar treatment of the second and third recipients led to maintenance of platelet counts of over 40 000 per μl throughout their 9‐ and 8‐day survivals, which represents the longest reported survival of pig‐to‐primate liver transplants to date. Both of the last two animals nevertheless succumbed to bleeding and enterococcal infection, without evidence of rejection. Conclusions:  These observations suggest that thrombocytopenia after liver xenotransplantation may be overcome by Amicar therapy. The coagulopathy and sepsis that nevertheless occurred suggest that additional causes of coagulation disturbance must be addressed, along with better prevention of infection, to achieve long‐term survival.     

Hyperacute rejection in ex vivo-perfused porcine lungs transgenic for human complement regulatory proteins

Inhibition of complement activation via human membrane-associated complement regulators is known to prevent hyperacute rejection in heart and kidney pig-to-primate transplantation. The protective effect of such strategies in pulmonary xenografts, however, seems to be insufficient. In an ex vivo perfusion, model lungs from donor pigs transgenic for human CD55 (n = 6) or human CD59 (n = 5) were perfused with fresh human blood and compared with nontransgenic organs (n = 6). In addition, a soluble complement component 1 esterase inhibitor (C1-Inh) was applied in h-CD55 transgenic lungs (n = 3). In the h-CD55 transgenic group, survival was prolonged (P < 0.05), quality and maximal time of oxygenation significantly improved and pulmonary vascular resistance reduced compared with the control group. There was a decreased sequestration of platelets, less parenchymal injury and reduced deposition of C(5b-9) in the h-CD55 transgenic group. Additional soluble complement inhibition (C1-Inh) did not prolong survival of h-CD55 transgenic lungs. Survival and pulmonary function in lungs expressing h-CD59 was not significantly different from parameters observed in nontransgenic lungs. In this ex vivo model of pig-to-primate lung transplantation, membrane-based complement inhibition resulted in significantly improved pulmonary function. However, minor histopathological injuries observed in these transgenic xenografts suggested only partial protection from pulmonary dysfunction by complement inhibition alone.     

Disseminated intravascular coagulation in association with pig-to-primate pulmonary xenotransplantation

BACKGROUND: Profound coagulopathy has been proposed as a barrier to xenotransplantation. Disseminated intravascular coagulation (DIC) has been observed with the rejection of renal and bone marrow xenografts but has not yet been described in pulmonary xenografts. METHODS: This study examined the coagulation parameters in five baboons that received pulmonary xenografts and one baboon that was exposed to porcine lung during an extracorporeal perfusion. Platelet counts, prothrombin times (PT), and levels of fibrinogen, D-dimers, and thrombin-antithrombin III complex (TAT) were analyzed. In addition, serum levels of plasminogen activator inhibitor-1 (PAI-1), thrombomodulin (TM), tissue plasminogen activator (tPA), and tissue factor (TF) were determined. RESULTS: Hyperacute pulmonary xenograft dysfunction, which occurred within 0-9 hr of graft reperfusion, was associated with clinically evident DIC. This coagulopathy was characterized by thrombocytopenia, decreased fibrinogen levels, elevations in PT, and increases in D-dimers and TAT. Furthermore, transient increases in PAI-1, increases in TM, and increases in tPA were observed in the serum of some but not all recipients. None of the baboons demonstrated measurable increases in soluble TF. CONCLUSIONS: Although DIC in renal or bone marrow xenotransplantation develops over a period of days, DIC associated with hyperacute pulmonary xenograft dysfunction develops within hours of graft reperfusion. Thus, the DIC in pulmonary xenotransplantation may represent a unique and/or accelerated version of the coagulopathy observed with renal and bone marrow xenotransplantation.     

C1-Inhibitor for treatment of acute vascular xenograft rejection in cynomolgus recipients of h-DAF transgenic porcine kidneys

Abstract: At present, the major barrier to successful discordant xenotransplantation of unmodified or complement regulator transgenic porcine xenografts is acute vascular xenograft rejection (AVR). AVR is associated with the intragraft deposition of induced recipient xenoreactive antibodies and subsequent complement activation. In a life-supporting pig to primate kidney xenotransplantation setting using h-DAF transgenic donor organs and postoperative immunosuppression, episodes of AVR were either treated with boluses of cyclophosphamide and steroids or with the same regimen supplemented by a three-day course of C1-Inhibitor, a multifunctional complement regulator. In 8 out of 10 animals stable initial graft function was achieved; in all animals one or more episodes of AVR were observed. When, in 4 animals, C1-Inhibitor was added to the standard anti-rejection treatment regimen, AVR was successfully reversed in 6 out of 7 episodes, while in another group of 4 animals receiving the standard anti-rejection treatment 0 out of 4 episodes of AVR responded to treatment. Response to anti-rejection treatment was associated with a significant increase in recipient survival time. We conclude that AVR of h-DAF transgenic porcine kidneys can be successfully treated by additional short-term fluid phase complement inhibition.     

Human complement regulatory proteins protect swine lungs from xenogeneic injury

BACKGROUND: Pulmonary xenotransplantation is not possible because of hyperacute lung injury, the pathogenesis of which is unknown. This study evaluates complement-dependent pathways of pulmonary injury during heterologous perfusion of swine lungs. METHODS: Lungs from unmodified swine and swine expressing human decay-accelerating factor and human CD59 (hDAF/hCD59 swine) were perfused with either human plasma or baboon blood. Pulmonary vascular resistance and static pulmonary compliance were measured serially, and swine lung tissue were examined by light microscopy. Complement activation was assessed by serial measurements of baboon plasma C3a-desArg concentrations. RESULTS: Perfusion of unmodified swine lungs with human plasma and baboon blood resulted in hyperacute lung injury within minutes of perfusion. However, function was preserved in swine lungs expressing human decay-accelerating factor and human CD59. In both study groups, xenogeneic perfusion with baboon blood resulted in at least a sevenfold increase in plasma C3a-desArg levels suggesting transient activation of complement. CONCLUSIONS: Lungs from swine expressing human decay-accelerating factor and human CD59 were resistant to injury during perfusion with human plasma and baboon blood, indicating that complement mediated some of the features of xenogeneic acute lung injury.     

Results of Gal‐Knockout Porcine Thymokidney Xenografts

Clinical transplantation for the treatment of end‐stage organ disease is limited by a shortage of donor organs. Successful xenotransplantation could immediately overcome this limitation. The development of homozygous α1,3‐galactosyltransferase knockout (GalT‐KO) pigs removed hyperacute rejection as the major immunologic hurdle to xenotransplantation. Nevertheless, GalT‐KO organs stimulate robust immunologic responses that are not prevented by immunosuppressive drugs. Murine studies show that recipient thymopoiesis in thymic xenografts induces xenotolerance. We transplanted life‐supporting composite thymokidneys (composite thymus and kidneys) prepared in GalT‐KO miniature swine to baboons in an attempt to induce tolerance in a preclinical xenotransplant model. Here, we report the results of seven xenogenic thymokidney transplants using a steroid‐free immunosuppressive regimen that eliminated whole‐body irradiation in all but one recipient. The regimen resulted in average recipient survival of over 50 days. This was associated with donor‐specific unresponsiveness in vitro and early baboon thymopoiesis in the porcine thymus tissue of these grafts, suggesting the development of T‐cell tolerance. The kidney grafts had no signs of cellular infiltration or deposition of IgG, and no grafts were lost due to rejection. These results show that xenogeneic thymus transplantation can support early primate thymopoiesis, which in turn may induce T‐cell tolerance to solid organ xenografts.     

Life-supporting human complement regulator decay accelerating factor transgenic pig liver xenograft maintains the metabolic function and coagulation in the nonhuman primate for up to 8 days

BACKGROUND: It is not known whether the pig liver is capable of functioning efficiently when transplanted into a primate, neither is there experience in transplanting a liver from a transgenic pigs expressing the human complement regulator human complement regulator decay accelerating factor (h-DAF) into a baboon. The objective of this study was to determine whether the porcine liver would support the metabolic functions of non-human primates and to establish the effect of hDAF expression in the prevention of hyperacute rejection of porcine livers transplanted into primates. METHODS: Five orthotopic liver xenotransplants from pig to baboon were carried out: three from unmodified pigs and two using livers from h-DAF transgenic pigs. FINDINGS: The three control animals transplanted with livers from unmodified pigs survived for less than 12 hr. Baboons transplanted with livers from h-DAF transgenic pigs survived for 4 and 8 days. Hyperacute rejection was not detected in the baboons transplanted with hDAF transgenic pig livers; however, it was demonstrated in the three transplants from unmodified pigs. Baboons transplanted with livers from h-DAF transgenic pigs were extubated at postoperative day 1 and were awake and able to eat and drink. In the recipients of hDAF transgenic pig livers the clotting parameters reached nearly normal levels at day 2 after transplantation and remained normal up to the end of the experiments. In these hDAF liver recipients, porcine fibrinogen was first detected in the baboon plasma 2 hr postreperfusion, and was present up to the end of the experiments. One animal was euthanized at day 8 after development of sepsis and coagulopathy, the other animal arrested at day 4, after an episode of vomiting and aspiration. The postmortem examination of the hDAF transgenic liver xenografts did not demonstrate rejection. INTERPRETATION: The livers from h-DAF transgenic pigs did not undergo hyperacute rejection after orthotopic xenotransplantation in baboons. When HAR is abrogated, the porcine liver maintains sufficient coagulation and protein levels in the baboon up to 8 days after OLT.     

Aurintricarboxylic acid inhibits endothelial activation, complement activation, and von Willebrand factor secretion in vitro and attenuates hyperacute rejection in an ex vivo model of pig-to-human pulmonary xenotransplantation

Abstract: Background: In the xenotransplantation of vascularized organs, such as the lung, a large area of endothelial cell layer is a big hurdle to be overcome. We investigated the potential protective effect of aurintricarboxylic acid (ATA), a known inhibitor of platelet adhesion, on endothelial damage induced by xenogeneic serum. We also assessed its role in hyperacute xenograft rejection using a porcine ex vivo lung perfusion model. Methods: Porcine endothelial cells were incubated with human serum and other inflammatory stimuli. For the evaluation of von Willebrand factor (vWF) secretion and tissue factor (TF) expression, we used human endothelial cells. E‐selectin expression, complement activation, TF expression and platelet activation were investigated by flow cytometry. In an ex vivo porcine lung perfusion model, the porcine lungs were perfused with fresh human whole blood: unmodified blood (n = 5), ATA‐treated blood (n = 5), and ATA and lepirudin‐treated blood (n = 5). Results: Aurintricarboxylic acid significantly inhibited TNF‐α‐ or lipopolysaccharide‐induced endothelial E‐selectin expression in a dose‐dependent manner. ATA also prevented human serum induced‐E‐selectin expression and human monocytic cell adhesion to porcine endothelial cells. Moreover, ATA abolished thrombin‐induced vWF secretion as well as complement activation. However, ATA induced endothelial TF expression and platelet activation in vitro. In ex‐vivo experiments, ATA treatment improved pulmonary function and attenuated sequestration of leukocytes. Although ATA did not influence thrombin generation, we were able to minimize its activity by adding lepirudin to the blood with ATA. Conclusions: Our study demonstrated in vitro protective effect of ATA on the inhibition of endothelial activation and vWF secretion and confirmed detrimental effect of ATA on induction of endothelial TF and platelet activation. The combination of ATA and lepirudin may act beneficially by preventing coagulation perturbation while maintaining improved xenograft survival.