Author Correction: Consistent success in life-supporting porcine cardiac xenotransplantation.

In this Letter, Mayuko Kurome and Valeri Zakhartchenko have been added to the author list (affiliated with Institute of Molecular Animal Breeding and Biotechnology, Gene Center, LMU Munich, Munich, Germany). The author list and 'Author contributions' section have been corrected online; see accompanying Amendment.

Transthoracic echocardiography is a simple tool for size matching in cardiac xenotransplantation.

BACKGROUND: Preoperative size matching is essential for both allogeneic and xenogeneic heart transplantation. In preclinical pig-to-baboon xenotransplantation experiments, porcine donor organs are usually matched to recipients by using indirect parameters, such as age and total body weight. For clinical use of xenotransplantation, a more precise method of size measurement would be desirable to guarantee a "perfect match." Here, we investigated the use of transthoracic echocardiography (TTE) and described a new method to estimate organ size prior to xenotransplantation. METHODS: Hearts from n = 17 genetically modified piglets were analyzed by TTE and total heart weight (THW) was measured prior to xenotransplantation into baboons between March 2018 and April 2022. Left ventricular (LV) mass was calculated according to the previously published method by Devereux et al. and a newly adapted formula. Hearts from n = 5 sibling piglets served as controls for the determination of relative LV and right ventricular (RV) mass. After explantation, THW and LV and RV mass were measured. RESULTS: THW correlated significantly with donor age and total body weight. The strongest correlation was found between THW and LV mass calculated by TTE. Compared to necropsy data of the control piglets, the Devereux formula underestimated both absolute and relative LV mass, whereas the adapted formula yielded better results. Combining the adapted formula and the relative LV mass data, THW can be predicted with TTE. CONCLUSIONS: We demonstrate reliable LV mass estimation by TTE for size matching prior to xenotransplantation. An adapted formula provides more accurate results of LV mass estimation than the generally used Devereux formula in the xenotransplantation setting. TTE measurement of LV mass is superior for the prediction of porcine heart sizes compared to conventional parameters such as age and total body weight.

Hemodynamics in pig-to-baboon heterotopic thoracic cardiac xenotransplantation: Recovery from perioperative cardiac xenograft dysfunction and impairment by cardiac overgrowth.

INTRODUCTION: Orthotopic cardiac xenotransplantation has seen notable improvement, leading to the first compassionate use in 2022. However, it remains challenging to define the clinical application of cardiac xenotransplantation, including the back-up strategy in case of xenograft failure. In this regard, the heterotopic thoracic technique could be an alternative to the orthotopic procedure. We present hemodynamic data of heterotopic thoracic pig-to-baboon transplantation experiments, focusing on perioperative xenograft dysfunction and xenograft overgrowth. METHODS: We used 17 genetically modified piglets as donors for heterotopic thoracic xenogeneic cardiac transplantation into captive-bred baboons. In all animals, pressure probes were implanted in the graft's left ventricle and the recipient's ascending aorta and hemodynamic data (graft pressure, aortic pressure and recipient's heart rate) were recorded continuously. RESULTS: Aortic pressures and heart rates of the recipients' hearts were postoperatively stable in all experiments. After reperfusion, three grafts presented with low left ventricular pressure indicating perioperative cardiac dysfunction (PCXD). These animals recovered from PCXD within 48 h under support of the recipient's heart and there was no difference in survival compared to the other 14 ones. After 48 h, graft pressure increased up to 200 mmHg in all 17 animals with two different time-patterns. This led to a progressive gradient between graft and aortic pressure. With increasing gradient, the grafts stopped contributing to cardiac output. Grafts showed a marked weight increase from implantation to explantation. CONCLUSION: The heterotopic thoracic cardiac xenotransplantation technique is a possible method to overcome PCXD in early clinical trials and an experimental tool to get a better understanding of PCXD. The peculiar hemodynamic situation of increasing graft pressure but missing graft's output indicates outflow tract obstruction due to cardiac overgrowth. The heterotopic thoracic technique should be successful when using current strategies of immunosuppression, organ preservation and donor pigs with smaller body and organ size.

Consistent success in life-supporting porcine cardiac xenotransplantation.

Heart transplantation is the only cure for patients with terminal cardiac failure, but the supply of allogeneic donor organs falls far short of the clinical need1-3. Xenotransplantation of genetically modified pig hearts has been discussed as a potential alternative4. Genetically multi-modified pig hearts that lack galactose-α1,3-galactose epitopes (α1,3-galactosyltransferase knockout) and express a human membrane cofactor protein (CD46) and human thrombomodulin have survived for up to 945 days after heterotopic abdominal transplantation in baboons5. This model demonstrated long-term acceptance of discordant xenografts with safe immunosuppression but did not predict their life-supporting function. Despite 25 years of extensive research, the maximum survival of a baboon after heart replacement with a porcine xenograft was only 57 days and this was achieved, to our knowledge, only once6. Here we show that α1,3-galactosyltransferase-knockout pig hearts that express human CD46 and thrombomodulin require non-ischaemic preservation with continuous perfusion and control of post-transplantation growth to ensure long-term orthotopic function of the xenograft in baboons, the most stringent preclinical xenotransplantation model. Consistent life-supporting function of xenografted hearts for up to 195 days is a milestone on the way to clinical cardiac xenotransplantation7.

Current Status of Cardiac Xenotransplantation: Report of a Workshop of the German Heart Transplant Centers, Martinsried, March 3, 2023.

This report comprises the contents of the presentations and following discussions of a workshop of the German Heart Transplant Centers in Martinsried, Germany on cardiac xenotransplantation. The production and current availability of genetically modified donor pigs, preservation techniques during organ harvesting, and immunosuppressive regimens in the recipient are described. Selection criteria for suitable patients and possible solutions to the problem of overgrowth of the xenotransplant are discussed. Obviously microbiological safety for the recipient and close contacts is essential, and ethical considerations to gain public acceptance for clinical applications are addressed. The first clinical trial will be regulated and supervised by the Paul-Ehrlich-Institute as the National Competent Authority for Germany, and the German Heart Transplant Centers agreed to cooperatively select the first patients for cardiac xenotransplantation.

Glycocalyx dynamics and the inflammatory response of genetically modified porcine endothelial cells.

Xenotransplantation is a promising approach to reduce organ shortage, while genetic modification of donor pigs has significantly decreased the immunogenic burden of xenotransplants, organ rejection is still a hurdle. Genetically modified pig organs are used in xenotransplantation research, and the first clinical pig-to-human heart transplantation was performed in 2022. However, the impact of genetic modification has not been investigated on a cellular level yet. Endothelial cells (EC) and their sugar-rich surface known as the glycocalyx are the first barrier encountering the recipient's immune system, making them a target for rejection. We have previously shown that wild type venous but not arterial EC were protected against heparan sulfate (HS) shedding after activation with human serum or human tumor necrosis factor alpha (TNF𝛼). Using a 2D microfluidic system we investigated the glycocalyx dynamics of genetically modified porcine arterial and venous EC (Gal𝛼1,3 Gal knock-out, transgenic for human CD46 and thrombomodulin, GTKO/hCD46/hTM) after activation with human serum or human TNF𝛼. Interestingly, we observed that GTKO/hCD46/hTM arterial cells, additionally to venous cells, do not shed HS. Unscathed HS on GTKO/hCD46/hTM EC correlated with reduced complement deposition, suggesting that protection against complement activation contributes to maintaining an intact glycocalyx layer on arterial EC. This protection was lost on GTKO/hCD46/hTM cells after simultaneous perfusion with human serum and human TNF𝛼. HS shedding on arterial cells and increased complement deposition on both arterial and venous cells was observed. These findings suggest that GTKO/hCD46/hTM EC revert to a proinflammatory phenotype in an inflammatory xenotransplantation setting, potentially favoring transplant rejection.

Cervical Debranching: Regional versus General Anesthesia for Carotid-Subclavian Bypass. A Single Center Experience.

BACKGROUND: We report here the first cohort study comparing regional and general anaesthesia for left subclavian artery (LSA) revascularization. METHODS: A single-centre retrospective cohort study was performed, including all consecutive patients who underwent cervical debranching with carotid-subclavian bypass before aortic repair from February 2018 to May 2022. Patients were divided into 2 groups according to the type of anesthesia: Regional anesthesia (RA) versus general anesthesia (GA). Primary endpoints included the following: 1) technical success of RA and 2) neurological complications (NCs) (stroke and peripheral neurological lesions). Secondary endpoints included postoperative bleeding, wound complications, 30-day reintervention rate, and midterm events. RESULTS: Eighty-three patients were included in the study. The mean age was 64 years (interquartile range [IQR]:13.5) and 69% were male. Thirty-seven patients (44.5%) were performed under RA. Technical success of RA was 89.2%. Two minor strokes (2.4%) were observed in the GA group (P = 0.199). Peripheral neurological disorders occurred in 4 patients (4.8%) (RA group n = 1 (2.7%), GA group n = 3 (6.5%), P = 0.491). 30-day complication rate was 27.7% (n = 23, GA: n = 15 (32.6%), RA: n = 8 (21.6%), P = 0.266). 30-day reintervention rate was 14.5% (n = 12) ten bleeding complications (12%) (RA group n = 3 (8.1%), GA group n = 7 (15.2%), P = 0.323), and 2 seroma evacuations (2.4%) in the RA group. The incidence of superficial wound infections was n = 6 (7.2%) (RA group n = 2 (5.4%), GA group n = 4 (8.7%), P = 0.565). Median follow-up time was 22 months (IQR 22 min/max 1-44). CONCLUSIONS: In our cohort, RA for carotid subclavian bypass surgery proved to be a feasible and effective anesthetic procedure compared with GA.

Overcoming perioperative inflammation as a hurdle for successful preclinical orthotopic cardiac xenogeneic transplantations - particular in regard of the mandatory use of heart-lung machines.

INTRODUCTION: After orthotopic cardiac xenotransplantation, the combination of both the inflammatory responses to the exposure of a recipient to the xenogeneic organ and the use of cardiopulmonary bypass has been assumed to cause detrimental side effects. These have been described not only to affect the transplanted organ (heart) itself, but also the recipient's lungs. In this article, we summarize how these possible detrimental processes can be minimized or even avoided. METHODS: Data from eight pig-to-baboon orthotopic cardiac xenotransplantation experiments were analyzed with a special focus on early (within the first week) postoperative organ dysfunction and systemic inflammatory responses. Non-ischemic heart preservation and the careful management of the heart-lung machine were deemed essential to guarantee not only the immediate function of the transplanted xenogeneic organ but also the prompt recovery of the recipient. RESULTS: After weaning from cardiopulmonary bypass, very low catecholamine amounts were needed to ensure an adequate pump function and cardiac output. Central venous oxygen saturation and serum lactate levels remained within normal ranges. All animals were successfully weaned from ventilation within the first postoperative hours. Serum parameters of the transplants and native kidneys and livers were initially slightly elevated or always normal, as were hemoglobin, LDH, and platelet measurements. Markers of systemic inflammation, C-reactive protein, and IL-6 were slightly elevated, but the reactions caused no lasting damage. CONCLUSION: Consistent short-term and long-term results were achieved after orthotopic cardiac pig-to-baboon transplantation without detrimental inflammatory responses or signs of multiorgan failure. In comparison to allogeneic procedures, non-ischemic heart preservation was important for successful immediate organ function, as was the management of the heart-lung machine. Thus, we believe that genetically modified porcine hearts are ready for use in the clinical setting.

First Experience with the Munich Valsalva Implantation Technique (MuVIT) for Cardiac Output Reduction During Standard and Complex Thoracic Endovascular Aortic Repair.

OBJECTIVE: The Munich Valsalva Implantation Technique (MuVIT) is a non-invasive alternative which uses a modified Valsalva manoeuvre to reduce cardiac output (CO). The aim of this study was to evaluate the technical success and safety of MuVIT in standard and complex endovascular thoracic aneurysm repair (TEVAR). METHODS: This was a retrospective single centre cohort study. Patients were included who underwent CO reduction with MuVIT between March 2020 and February 2021 for standard and fenestrated/branched TEVAR (fbTEVAR). The target systolic blood pressure (SBP) reduction was used as an indicator of CO reduction. The aim of the SBP reduction was 50% in patients undergoing proximal sealing in Ishimaru zones 0-1 (Group 1), and 30% in patients with sealing in Ishimaru zones 2-3 (Group 2). Efficacy outcomes included MuVIT technical success and procedural technical success. Safety outcomes included MuVIT and procedural related complications in the first 30 days. RESULTS: During the study period 52 cases were screened for MuVIT. Of these, 40 patients (77%) underwent procedures that were performed under MuVIT. Exclusion reasons were local anaesthesia (n = 9); pulmonary contraindications (n = 2), and poor heart pump function (n = 1). Fifteen patients (37.5%) underwent bTEVAR, three patients (7.5%) fTEVAR, and 22 patients (55%) standard TEVAR. Twenty nine (72.5%) procedures were elective, seven (17.5%) were urgent, and four (10%) were as an emergency. Successful proximal endograft deployment under MuVIT was 100%. The target SBP reduction was achieved in 95% (Group 1: 89.5%, Group 2: 100%), with an overall mean reduction of 46% (Group 1: 55%, Group 2: 40%). The 30 day mortality was 7.5%, and was not MuVIT related. Two patients with COPD Gold III/IV developed respiratory complications. CONCLUSION: MuVIT is a safe and effective manoeuvre for CO reduction during aortic arch TEVAR. However, careful patient selection is required and potential adverse effects on patients with severe COPD needs further evaluation.

Cold non-ischemic heart preservation with continuous perfusion prevents early graft failure in orthotopic pig-to-baboon xenotransplantation.

BACKGROUND: Successful preclinical transplantations of porcine hearts into baboon recipients are required before commencing clinical trials. Despite years of research, over half of the orthotopic cardiac xenografts were lost during the first 48 hours after transplantation, primarily caused by perioperative cardiac xenograft dysfunction (PCXD). To decrease the rate of PCXD, we adopted a preservation technique of cold non-ischemic perfusion for our ongoing pig-to-baboon cardiac xenotransplantation project. METHODS: Fourteen orthotopic cardiac xenotransplantation experiments were carried out with genetically modified juvenile pigs (GGTA1- KO/hCD46/hTBM) as donors and captive-bred baboons as recipients. Organ preservation was compared according to the two techniques applied: cold static ischemic cardioplegia (IC; n = 5) and cold non-ischemic continuous perfusion (CP; n = 9) with an oxygenated albumin-containing hyperoncotic cardioplegic solution containing nutrients, erythrocytes and hormones. Prior to surgery, we measured serum levels of preformed anti-non-Gal-antibodies. During surgery, hemodynamic parameters were monitored with transpulmonary thermodilution. Central venous blood gas analyses were taken at regular intervals to estimate oxygen extraction, as well as lactate production. After surgery, we measured troponine T and serum parameters of the recipient's kidney, liver and coagulation functions. RESULTS: In porcine grafts preserved with IC, we found significantly depressed systolic cardiac function after transplantation which did not recover despite increasing inotropic support. Postoperative oxygen extraction and lactate production were significantly increased. Troponin T, creatinine, aspartate aminotransferase levels were pathologically high, whereas prothrombin ratios were abnormally low. In three of five IC experiments, PCXD developed within 24 hours. By contrast, all nine hearts preserved with CP retained fully preserved systolic function, none showed any signs of PCXD. Oxygen extraction was within normal ranges; serum lactate as well as parameters of organ functions were only mildly elevated. Preformed anti-non-Gal-antibodies were similar in recipients receiving grafts from either IC or CP preservation. CONCLUSIONS: While standard ischemic cardioplegia solutions have been used with great success in human allotransplantation over many years, our data indicate that they are insufficient for preservation of porcine hearts transplanted into baboons: Ischemic storage caused severe impairment of cardiac function and decreased tissue oxygen supply, leading to multi-organ failure in more than half of the xenotransplantation experiments. In contrast, cold non-ischemic heart preservation with continuous perfusion reliably prevented early graft failure. Consistent survival in the perioperative phase is a prerequisite for preclinical long-term results after cardiac xenotransplantation.

Hemodynamic evaluation of anesthetized baboons and piglets by transpulmonary thermodilution: Normal values and interspecies differences with respect to xenotransplantation.

BACKGROUND: Transpulmonary thermodilution is well established as a tool for in-depth hemodynamic monitoring of critically ill patients during surgical procedures and intensive care. It permits easy assessment of graft function following cardiac transplantation and guides post-operative volume and catecholamine therapy. Since no pulmonary catheter is needed, transpulmonary thermodilution could be useful in experimental cardiac pig-to-baboon xenotransplantation. However, normal values for healthy animals have not yet been reported. Here, we present data from piglets and baboons before xenotransplantation experiments and highlight differences between the two species and human reference values. METHODS: Transpulmonary thermodilution from baboons (body weight 10-34 kg) and piglets (body weight 10-38kg) were analyzed. Measurements were taken in steady state after induction of general anesthesia before surgical procedures commenced. Cardiac index (CI), mean arterial pressure (MAP), systemic vascular resistance index (SVRI), parameters quantifying cardiac filling (global end-diastolic volume index, GEDI), and pulmonary edema (extravascular lung water, ELWI) were assessed. RESULTS: Preload, afterload, and contractility parameters clearly correlated with total body weight or body surface area. Baboons had lower CI values than weight-matched piglets (4.2 ± 0.9l/min/m2 vs 5.3 ± 1.0/min/m2 , P < .01). MAP and SVRI were higher in baboons than piglets (MAP: 99 ± 22 mm Hg vs 62 ± 11 mm Hg, P < .01; SVRI: 1823 ± 581 dyn*s/cm5 *m2 vs 827 ± 204 dyn*s/cm5 *m2 , P < .01). GEDI and ELWI did differ significantly between both species, but measurements were within similar ranges (GEDI: 523 ± 103 mL/m2 vs 433 ± 78 mL/m2 , P < .01; ELWI: 10 ± 3 mL/kg vs 11 ± 2 mL/kg, P < .01). Regarding adult human reference values, CI was similar to both baboons and piglets, but all other parameters were different. CONCLUSIONS: Parameters of preload, afterload, and contractility differ between baboons and piglets. In particular, baboons have a much higher afterload than piglets, which might be instrumental in causing perioperative xenograft dysfunction and post-operative myocardial hypertrophy after orthotopic pig-to-baboon cardiac xenotransplantation. Most transpulmonary thermodilution-derived parameters obtained from healthy piglets and baboons lie outside the reference ranges for humans, so human normal values should not be used to guide treatment in those animals. Our data provide reference values as a basis for developing algorithms for perioperative hemodynamic management in pig-to-baboon cardiac xenotransplantation.

Induction of porcine-specific regulatory T cells with high specificity and expression of IL-10 and TGF-ß1 using baboon-derived tolerogenic dendritic cells.

BACKGROUND: Regulatory T cells (Treg) play an important role in maintenance of homeostasis in vivo. Treg application to alleviate allo-organ rejection is being studied extensively. However, natural Treg (nTreg) expansion in vitro is laborious and expensive. Antigen-specific Treg are more effective and require lower cell numbers than use of nTreg for immune control. The baboon, as a non-human primate experimental animal model, is widely used in xenotransplantation research. An effective method to generate baboon xeno-specific Treg would benefit research on immune tolerance in xenotransplantation using this model system. METHOD: Baboon tolerogenic dendritic cells (tolDC) were generated in 3 days from monocytes isolated from baboon peripheral blood mononuclear cells in medium supplemented with anti-inflammatory cytokines. After loading with porcine-specific (PS) in vitro-transcribed RNA (ivtRNA), tolDC were used to induce CD4+ T cells to become porcine-specific Treg (PSTreg) in cocultures supplemented with IL-2 and rapamycin for 10 days. Anti-inflammatory and inflammatory cytokine expression was evaluated at the mRNA and protein levels in both baboon tolDC and PSTreg. Functional assays, suppression of activation markers on porcine-specific effector T cells (PSTeff) and inhibition of PSTeff proliferation, were used to test PSTreg specificity. RESULTS: TolDC generated with this method exhibited a tolerogenic phenotype, expressed CCR7 and produced high levels of IL-10 and TGF-ß1, whereas IL-12p40 and IFN-γ were not expressed. PSTreg were successfully generated in cocultures of CD4+ T cells and PS ivtRNA-loaded tolDC. They exhibited a CD3+  CD4+  CD25+  CD127low/-  CD45RAlow  Foxp3+ phenotype and were characterized by high expression of IL-10 and TGF-ß1 mRNA and protein. They showed upregulated expression of EBI3 and GARP mRNA. PSTreg exhibited highly suppressive effects toward PSTeff, secreting high amounts of IL-10 and TGF-ß1 cytokine upon interaction with PSTeff and suppressing IFN-γ expression on PSTeff. CONCLUSION: In this study, a fast 3-day method to generate baboon-derived tolDC is provided that allows subsequent induction of PSTreg displaying high porcine-antigen specificity and expression of IL-10 and TGF-ß1. Porcine-specific baboon Treg can be used in porcine solid organ or cell xenotransplantation studies through adoptive cell transfer into host baboons.

Multiple genetically modified GTKO/hCD46/HLA-E/hß2-mg porcine hearts are protected from complement activation and natural killer cell infiltration during ex vivo perfusion with human blood.

BACKGROUND: In pig-to-human xenotransplantation, early cellular rejection reactions are mediated by natural killer cells (NK cells). Human NK cells are inhibited by HLA-E via CD94/NKG2A receptors. To protect porcine grafts against human NK cell responses, transgenic GTKO pigs expressing hCD46 and HLA-E have been generated. The aim of this study was to test the effect of this genetic modification on xenogeneic, and in particular human NK cell response, using an ex vivo perfusion model of pig hearts with human blood. METHODS: Cardiopleged and explanted genetically modified (gm) pig hearts (GTKO/hCD46/HLA-E/hß2-microglobulin) and wild-type (wt) controls (n = 6 each) were reperfused and tested in an 8 hours ex vivo perfusion system using freshly drawn human blood. Cardiac function was evaluated during a 165-minute period in working heart mode. Myocardial damage, antibody deposition, complement activation, and coagulation parameters were evaluated histologically at the end of perfusion. The number of NK cells in the perfusate was determined by flow cytometry at baseline and at 8 hours; tissue infiltration by NK cells was quantified by immunofluorescence microscopy using NKp46 staining of frozen sections. RESULTS: Deposition of IgG (1.2 ± 1 × 107 vs 8.8 ± 2.9 × 106 ; P < .01), IgM (4.4 ± 3.7 × 106 vs 1.7 ± 1.2 × 106 ; P < .01), and the complement activation product C4b/c (3.5 ± 1.3 × 106 vs 2.3 × 106  ± 9.4 × 105 ; P > .01) was lower in gm than wt hearts. NK cell percentages of leukocytes in the perfusate decreased from 0.94 ± 0.77% to 0.21 ± 0.25% (P = .04) during xenoperfusion of wt hearts. In contrast, the ratio of NK cells did not decrease significantly in the gm hearts. In this group, NK cell myocardial infiltration after 480 minutes of perfusion was lower than in wt organs (2.5 ± 3.7 × 104 /mm3 vs 1.3 ± 1.4 × 105 /mm3 ; P = .0001). The function of gm hearts was better preserved compared to wt organs, as demonstrated by higher cardiac index during the first 2 hours of ex vivo perfusion. CONCLUSION: GTKO, hCD46, and HLA-E expression in porcine hearts reduced complement deposition, complement dependent injury, and myocardial NK cell infiltration during perfusion with human blood. This tested combination of genetic modifications may minimize damage from acute human-anti-pig rejection reactions and improve myocardial function after xenotransplantation.

Large-Animal Biventricular Working Heart Perfusion System with Low Priming Volume-Comparison between in vivo and ex vivo Cardiac Function.

BACKGROUND: Existing large-animal, ex vivo, cardiac perfusion models are restricted in their ability to establish an ischemia/reperfusion condition as seen in cardiac surgery or transplantation. Other working heart systems only challenge one ventricle or require a substantially larger priming volume. We describe a novel biventricular cardiac perfusion system with reduced priming volume. METHODS: Juvenile pig hearts were cardiopleged, explanted, and reperfused ex vivo after 150 minutes of cold ischemia. Autologous whole blood was used as perfusate (minimal priming volume 350 mL). After 15 minutes of Langendorff perfusion (LM), the system was switched into a biventricular working mode (WM) and studied for 3 hours. RESULTS: During reperfusion, complete unloading of both ventricles and constant-pressure coronary perfusion was achieved. During working mode perfusion, the preload and afterload pressure of both ventricles was controlled within the targeted physiologic range. Functional parameters such as left ventricular work index were reduced in ex vivo working mode (in vivo: 787 ± 186 vs. 1 h WM 498 ± 66 mm Hg·mL/g·min; p < 0.01), but remained stable throughout the following study period (3 h WM 517 ± 103 mm Hg·mL/g·min; p = 0.63). Along with the elevated workload during WM, myocardial metabolism and oxygen consumption increased compared with LM (0.021 ± 0.08 vs. 0.06 ± 0.01 mL/min/g; 1 h after reperfusion). Histologic examination of the myocardium revealed no structural damage. CONCLUSION: In the ex vivo perfusion system, stable hemodynamic and metabolic conditions can be established for a period of 3 hours while functional and blood parameters are easily accessible. Moreover, because of the minimal priming volume, the novel ex vivo cardiac perfusion circuit allows for autologous perfusion, using the limited amount of blood available from the organ donating animal.

Hemodynamic and perioperative management in two different preclinical pig-to-baboon cardiac xenotransplantation models.

BACKGROUND: The perioperative phase of preclinical cardiac xenotransplantations significantly affects the experimental outcome. Moderate or even severe hemodynamic and respiratory impairment occurs frequently in baboons after receiving a cardiac transplant. The perioperative management of such postoperative instability is very demanding, especially in the experimental setting. We compared perioperative changes of hemodynamic and laboratory findings during orthotopic and heterotopic thoracic cardiac xenotransplantations and describe our monitoring, treatment and intensive care. METHODS: Twenty-eight pig-to-baboon cardiac xenotransplantations were performed using either the orthotopic (oHTx, n=5) or heterotopic thoracic (htHTx; n=23) technique. In both techniques, cardioplegia and an intraoperative cardiopulmonary bypass (CPB) were required. Preoperatively, intensive care (eg, transfusions, catecholamine therapy) was provided and fast extubation was targeted. A central venous catheter, a femoral arterial thermodilution catheter, a telemetric pressure transmitter and transthoracic echocardiography were used to monitor the animal. Baboon jackets with a tethering system were used to continuously apply medication postoperatively and permit blood sampling, also after extubation of the animal and transfer into the cage. Perioperative survival, hemodynamics, catecholamine doses, respiratory function and weaning from respirator were compared. Perioperative organ damage was evaluated based on laboratory findings 12 hours after transplantation. RESULTS: Recipients could be weaned from CPB in the 20 htHTx and all five oHTx experiments, and three htHTx procedures were terminated during the operation. The time of cardiopulmonary bypass was significantly lower in the heterotopic group (oHTx median 171 [157-193] minutes; htHTx median 144 [100-190] minutes; P=.02). In 17 htHTx procedures, no inotropics were used, whereas epinephrine had to be administered in four of the five oHTx experiments; the mean time of catecholamine support was longer in the oHTx group (oHTx 972±348 minutes vs htHTx 111±92 minutes; P<.01). After htHTx, weaning off the respirator was possible in 19 of 20 cases (one died due to pneumothorax). After oHTx, three of the five baboons could be weaned off the respirator; in these cases, the arterial saturation was higher compared with the extubated baboons after htHTx (oHTx 99±1% vs htHTx 91±4%, P=.01). Intraoperative blood loss was similar between the two groups, and hemostasis was impaired after all procedures, but relevant postoperative bleeding never occurred. CONCLUSION: Intensive intra- and postoperative monitoring and care is required in both transplantation techniques as a requirement for successful weaning from CPB and respirator. After htHTx, the animals needed less catecholamines and were hemodynamically more stable. Even though pulmonary function was often impaired after htHTx, weaning from the respirator and extubation was more successful in this group.

Complement C3 inhibitor Cp40 attenuates xenoreactions in pig hearts perfused with human blood.

BACKGROUND: The complement system plays a crucial role in acute xenogeneic reactions after cardiac transplantation. We used an ex vivo perfusion model to investigate the effect of Cp40, a compstatin analog and potent inhibitor of complement at the level of C3. METHODS: Fifteen wild-type pig hearts were explanted, cardiopleged, and reperfused ex vivo after 150 minutes of cold ischemia. Hearts were challenged in a biventricular working heart mode to evaluate cardiac perfusion and function. In the treatment group (n=5), the complement cascade was blocked at the level of C3 using Cp40, using diluted human blood. Untreated human and porcine blood was used for controls. RESULTS: Throughout the perfusion, C3 activation was inhibited when Cp40 was used (mean of all time points: 1.11 ± 0.34% vs 3.12 ± 0.48% control activation; P<.01). Compared to xenoperfused controls, the cardiac index improved significantly in the treated group (6.5 ± 4.2 vs 3.5 ± 4.8 mL/min/g; P=.03, 180 minutes perfusion), while the concentration of lactate dehydrogenase as a maker for cell degradation was reduced in the perfusate (583 ± 187 U/mL vs 2108 ± 1145 U/mL, P=.02). Histological examination revealed less hemorrhage and edema, and immunohistochemistry confirmed less complement fragment deposition than in untreated xenoperfused controls. CONCLUSIONS: Cp40 efficiently prevents C3 activation of the complement system, resulting in reduced cell damage and preserved function in wild-type porcine hearts xenoperfused ex vivo. We suggest that this compstatin analog, which blocks all main pathways of complement activation, could be a beneficial perioperative treatment in preclinical and in future clinical xenotransplantation.

Inhibition of complement component C5 prevents clotting in an ex vivo model of xenogeneic activation of coagulation.

BACKGROUND: Xenogeneic thrombotic microangiopathy (TMA) and acute vascular rejection (AVR) prevent long-term survival of porcine xenografts after transplantation into non-human primates. Preformed xenoreactive natural antibodies (XNA) cause endothelial damage and activate the complement system. Mechanisms of xenogeneic coagulation and platelet activation are only poorly characterized. METHODS: A microfluidic flow chamber was used to study platelet activation and thrombus formation of human platelet-rich plasma (PRP) upon perfusion over wild-type (WT) or α-1,3- galactosyltransferase knockout (GTKO) and human CD46 (hCD46) transgenic porcine aortic endothelial cells (PAEC). Activation of plasma coagulation (thrombin-anti-thrombin complex; TAT) and complement (C3a, C5a) was studied in human platelet-free plasma (PFP) after co-incubation with PAEC. The activation of PAEC (E-Selectin, tissue factor, ICAM-1, ICAM-2, VCAM-1) was studied after incubation with human serum. Eculizumab (200 µg/ml) was used to inhibit terminal complement activation in all experiments. RESULTS: WT-PAEC perfused with human PRP showed thrombus formation at different shear rates (3 dyn/cm(2) : 23 ± 10%; 10 dyn/cm(2) : 17 ± 10% of flow chamber viewing field). GTKO/hCD46 PAEC exhibited reduced, but not fully prevented thrombus formation (3 dyn/cm(2) : 12 ± 12%). Porcine PRP caused little or no thrombus formation (3.0 ± 4% and 0.5 ± 0.9%, respectively). Flow cytometry of human platelets after perfusion over WT-PAEC revealed an increase in platelet CD62P expression (29.5 ± 3%), compared to non-perfused PRP (7 ± 2%) or PRP running through empty flow chambers (12.7 ± 0.3%). Incubation of human PFP with PAEC resulted in an increase of TAT that correlated with C5a activation. Specific inhibition of complement by eculizumab prevented thrombus formation (WT-PAEC: 1.6 ± 2% at 3 dyn/cm(2) and 0.24 ± 0.33% at 10 dyn/cm(2) , GTKO/hCD46 PAEC: 0.2 ± 0.3% at 3 dyn/cm(2) ) as well as activation of coagulation and platelets. Induction of endothelial E-Selectin and VCAM-1 in WT-PAEC upon incubation with human serum was significantly reduced by eculizumab. Eculizumab did not reduce thrombin generation capacity of human PRP or normal platelet aggregation. CONCLUSION: Thrombus formation in this ex vivo model of xenogeneic TMA was closely linked with complement activation. Specific inhibition of complement C5 by eculizumab prevented endothelial cell activation, but also coagulation and platelet activation without compromising thrombin generation capacity of human blood or normal platelet function.

Pre-clinical heterotopic intrathoracic heart xenotransplantation: a possibly useful clinical technique.

BACKGROUND: As a step towards clinical cardiac xenotransplantation, our experimental heterotopic intrathoracic xenotransplantation model offers a beating and ejecting donor heart while retaining the recipient's native organ as a backup in case of graft failure. Clinically applicable immunosuppressive regimens (IS) were investigated first, then treatments known to be effective in hypersensitized patients or those with recalcitrant rejection reactions. METHODS: Consecutive experiments were carried out between 2009 and 2013. Twenty-one genetically modified pigs (GGTA1-knockout/hCD46/± thrombomodulin, in one case HLA-E instead) were used as donors. In all experiments, two cycles of immunoabsorption reduced preformed antibodies. Recipient baboons were divided into two groups according to IS regimen: In group one (n = 10), pre-treatment started either one (anti-CD20) or four weeks (anti-CD20 plus the proteasome inhibitor bortezomib) prior to transplantation. The extended conventional (as for allotransplantation) immunosuppressive maintenance regimen included anti-thymocyte globuline, tacrolimus, mycophenolate mofetil, methylprednisolone and weekly anti-CD20. In group two (n = 11), myeloablative pre-treatment as in multiple myeloma patients (long and short regimens) was added to extended conventional IS; postoperative total thoracic and abdominal lymphoid irradiation (TLI; single dose of 600 cGY) was used to further reduce antibody-producing cells. RESULTS: In the perioperative course, the surgical technique was safely applied: 19 baboons were weaned off extracorporeal circulation and 17 extubated. Nine animals were lost in the early postoperative course due to causes unrelated to surgical technique or IS regimen. Excluding these early failures, median graft survival times of group 1 and 2 were 18.5 (12-50) days and 16 (7-35) days. Necropsy examination of group 1 donor organs revealed hypertrophy of the left ventricular wall in the six longer-lasting grafts; myocardial histology confirmed pre-clinical suspicion of humoral rejection, which was not inhibited by the extended conventional IS including intensified treatments, and signs of thrombotic microangiopathy. Grafts of group 2 presented with only mild-to-moderate features of humoral rejection and thrombotic microangiopathy, except in one case of delayed rejection on day 17. The other experiments in this group were terminated because of untreatable pulmonary oedema, recurring ventricular fibrillation, Aspergillus sepsis, as well as a combination of a large donor organ and late toxic side effects due to TLI. CONCLUSIONS: Longer-term results were difficult to achieve in this model due to the IS regimens used. However, we conclude that heterotopic intrathoracic heart transplantation may be an option for clinical xenotransplantation.

Xenotransplantation of Cells, Tissues, Organs and the German Research Foundation Transregio Collaborative Research Centre 127.

Human organ transplantation is the therapy of choice for end-stage organ failure. However, the demand for organs far exceeds the donation rate, and many patients die while waiting for a donor. Clinical xenotransplantation using discordant species, particularly pigs, offers a possible solution to this critical shortfall. Xenotransplantation can also increase the availability of cells, such as neurons, and tissues such as cornea, insulin producing pancreatic islets and heart valves. However, the immunological barriers and biochemical disparities between pigs and primates (human) lead to rejection reactions despite the use of common immunosuppressive drugs. These result in graft vessel destruction, haemorrhage, oedema, thrombus formation, and transplant loss. Our consortium is pursuing a broad range of strategies to overcome these obstacles. These include genetic modification of the donor animals to knock out genes responsible for xenoreactive surface epitopes and to express multiple xenoprotective molecules such as the human complement regulators CD46, 55, 59, thrombomodulin and others. We are using (new) drugs including complement inhibitors (e.g. to inhibit C3 binding), anti-CD20, 40, 40L, and also employing physical protection methods such as macro-encapsulation of pancreatic islets. Regarding safety, a major objective is to assure that possible infections are not transmitted to recipients. While the aims are ambitious, recent successes in preclinical studies suggest that xenotransplantation is soon to become a clinical reality.