Ischemia/reperfusion injury of porcine limbs after extracorporeal perfusion.

BACKGROUND: Revascularization of amputated extremities after prolonged ischemia is complicated by reperfusion injury. We assessed ischemia/reperfusion (I/R) injury of porcine extremities after prolonged preservation using extracorporeal circulation (ECC). METHODS: Forelimbs of 32 pigs were divided into four groups based on ischemia times: group I: 6 h, group II: 12 h, group III: 0 h plus replantation, and group IV: 6 h plus replantation. Limbs were perfused with autologous blood using ECC for 12 h except group II with only 5 h perfusion. Limbs from groups III and IV were heterotopically replanted with a 7-d follow-up. Contralateral limbs served as controls in all groups. Tissue, plasma, and serum were analyzed for the extent of I/R injury. RESULTS: No significant differences in tissue wet/dry ratios were found within or between groups. This finding was confirmed by histology, except for an increased damage in group IV muscles compared with baseline (P = 0.016). Complement C3 deposition was only increased in group IV muscle (P = 0.031), group II nerves (P = 0.046), and group II vessels (P = 0.037). Group IV muscle and nerve tissues were the only ones with significant IgM antibody deposition (P = 0.031) at end of perfusion. Values were normal again after replantation. Reduced complement activity and elevated IL-6, IL-8, MCP-1, VEGF, PDGF-bb, bFGF, and complement split products were found during perfusion but were normal again after replantation. Staining for heparin sulfate proteoglycans and von Willebrand factor confirmed minimal activation of endothelial cells. CONCLUSION: The results demonstrate that prolonged limb preservation using ECC has minimal impact on I/R-induced tissue injury. Extracorporeal perfusion is a potential limb-preserving technique encouraging further studies for use in limb revascularization.

Evaluation of a porcine whole-limb heterotopic autotransplantation model.

BACKGROUND: Recently performed vascularized composite tissue allotransplantations (CTAs) stimulate the ongoing research in the area of whole-limb transplantation. A reliable in vivo animal model is required for investigations in vascularized whole-limb CTA. The model should allow in vivo assessment in whole-limb preservation, allograft and xenograft response, and host immunomodulation. The goal of this study is to describe and evaluate the in vivo feasibility and reproducibility of a whole-limb porcine model as a basis for future research in this field. MATERIALS AND METHODS: In seven large white pigs, one forelimb was amputated under anesthesia and autotransplanted heterotopically with an arc of rotation of 180° and partially placed in a subcutaneous pocket. Clinical parameters were monitored and muscle biopsies were analyzed using ultrastructural morphological assessment of mitochondria quality after an observation period of 7 days. RESULTS: All animals could fully mobilize postoperatively without restrictions. At sacrifice, the anastomosed pedicle vessels of the limb were patent in six animals. In one pig, venous thrombosis could be observed. Muscle response was triggered following direct electrostimulation in six replanted limbs. The replanted extremities gained 12.97% weight within 7 days postreplantation compared with the amputation baseline values (P = 0.464 while maintaining normal compartment pressures at sacrifice (8.25 ± 5.31 cmH(2)O, P = 0.60). The ultrastructural evaluation of mitochondria morphology revealed intact mitochondria without signs of ischemia/reperfusion damage. CONCLUSION: This porcine model proved feasible, reliable, and reproducible for whole-limb autotransplantation. It presents significant potential in future preclinical research of whole-limb CTA transplantation.