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.

Adeno-associated viral vector 2.9 thymosin ß4 application attenuates rejection after heart transplantation: results of a preclinical study in the pig.

BACKGROUND: Graft survival is the most important factor for morbidity and mortality in cardiac transplantation. Improved immunosuppression significantly reduced early graft rejection. However, acute rejection may predispose to chronic rejection. Targeting both phases of the recipient's immune-reactivity by means of long-acting recombinant adeno-associated viral vectors (AAVs) encoding anti-inflammatory and cardioprotective factors appears to be a promising therapeutic approach. We investigate thymosin ß4 (Tß4) possessing anti-inflammatory and prosurvival abilities, as a means for pretransplant gene therapy. METHODS: Heterotopic, abdominal transplantation of cardiac allografts into landrace or into Munich mini pigs (n=5 per group) was performed. Transplants were transduced with AAV2.9 before transplantation by means of in situ perfusion of the donor organ. Vascuar endothelial growth factor and AAV2.9.Tß4 or AAV2.9.LacZ were added to the autologous blood used for perfusing the grafts for a period of 45 min. Immunosuppression was applied for 10 days after the operation. Transgene expression, capillary density, graft function, survival, and rejection were assessed. RESULTS: The AAV2.9 transduction induced robust overexpression of the transgene. In addition, Tß4 ameliorated inflammation, necrosis, vascular reaction (acute rejection) and in parallel improved capillary density. In addition, graft survival was significantly prolonged (10±3 days AAV2.9.LacZ vs. 31±4 days AAV2.9.Tß4). In the mini pig model, regional myocardial function of the grafts was improved by Tß4 transduction compared to LacZ (9.1%±0.9% subendocardial segment shortening in AAV2.9.LacZ vs. 15.8%±2.3% in AAV2.9.Tß4). CONCLUSION: In situ AAV2.9-mediated gene transfer of thymosin ß4 attenuated graft rejection in a heterotopic heart transplantation model. Perioperative cardioprotection by means of gene therapy might improve graft survival in cardiac allotransplantation.

Heart xenotransplantation in primate models.

Xenotransplantation is a potential solution for the worldwide persisting donor organ shortage. However, immunological and physiological barriers need to be overcome before the first clinical trials can be started. Nonhuman primates are considered the most suitable recipients in preclinical xenotransplantation models. Heterotopic abdominal cardiac xenotransplantation is a well-established nonworking heart model for immunological and biological studies on acute and delayed xenograft rejection and xenograft survival. Nevertheless, orthotopic life-supporting pig-to-baboon heart transplantation is the only accepted model for future cardiac xenotransplantation in humans so far. Survival times of 3 months in at least 60% of consecutive experiments have to be achieved and a minimum number of ten nonhuman primates have to survive for this period of time before clinical transplantation may be started. We recently introduced the heterotopic thoracic technique of pig-to-baboon heart transplantation. We believe that this technique combines the advantages of a working heart model with the safety of heterotopic transplantation. We describe the technical procedure of the three different pig-to-baboon models and give detailed information on perioperative care of the recipients.

First experience with heterotopic thoracic pig-to-baboon cardiac xenotransplantation.

BACKGROUND: Heterotopic thoracic heart transplantation may be an alternative to the established heterotopic abdominal or orthotopic cardiac xenotransplantation model as it combines the safety of heterotopic transplantation with the benefit of a working heart model. METHODS: In a first series of two animals, we tested the surgical feasibility of this procedure with non-transgenic pig hearts transplanted into pre-sensitized baboons (killed after weaning from cardiopulmonary bypass). In a second group (n = 2), double-transgenic alpha(1,3)galactosyl-transferase knock out/hCD46 pig hearts were transplanted into naïve baboons after immunoadsorption. The immunosuppressive regimen consisted of anti-CD20-mAb, tacrolimus, sirolimus, MMF and steroids. RESULTS: The first baboon was successfully transplanted, but died of an air embolism, while in the second animal graft survival was 50 days with the recipient in good physical condition. One rejection reaction was successfully treated by immunoadsorption, ATG and the proteasome inhibitor bortezomib. Post-mortem histopathology showed no evidence for humoral or cellular rejection of the cardiac xenograft. CONCLUSIONS: This is the first description of a heterotopic thoracic pig-to-baboon heart transplantation. The procedure combines the advantages of a working heart model with the safety of heterotopic transplantation. In contrast to orthotopic transplantation, the recipient heart can assist the donor heart during episodes of rejection. We believe that the heterotopic thoracic model may accelerate the progress into the clinical application of cardiac xenotransplantation. However, successful combination of this heterotopic transplantation with an experimental model of cardiac failure may be needed before this technique can be promoted to clinical trials.