Objective: The treatment of segmental bone defects remains challenging as complications frequently occur with the currently available methods, including vascularized autograft, prosthetic replacement, bone transport, and cryopreserved bone allograft (CBA). Although the use of CBA is comparatively simple, it lacks donor site morbidity and provides immediate stability; however, the grafts remain largely necrotic, resulting in high failure rates due to nonunion, infection, and stress fractures. Revitalizing the CBA has the potential to solve these problems. Previous studies in small animal models have shown the use of surgical revascularization to induce neoangiogenesis and improve bone viability in the CBA. The purpose of this study is to investigate if surgical revascularization enhances bone circulation and bone remodeling in a tibial defect orthotopic reconstruction model, placing a cryopreserved allograft in a Yucatan mini pig. Methods: Cryopreserved tibial bone allografts were transplanted in swine leukocyte antigen (SLA)-type-mismatched Yucatan mini pigs after creating a 3.5-cm segmental bone defect in the tibia. The anterior tibial arteriovenous bundle (AV-bundle) was inserted into the intramedullary canal. Eight pigs received a patent AV-bundle (revascularized group), 8 pigs received a proximally ligated AV-bundle (control group), and the contralateral side was used as an untreated control. The graft was fixated with a locking compression plate to provide a weightbearing construction. After 20 weeks, the pigs were killed and the tibia was removed and analyzed. Neoangiogenesis was evaluated by quantifying vascular volumes using the microcomputed tomography. Bone remodeling was measured by quantitative histomorphometry and micro-computed tomography. Results: Seven AV-bundles in the revascularized group were patent and 1 bundle was thrombosed due to partial dislocation of the graft. Total vascular volume was higher in the revascularized allografts (127 mm3) compared with both the control group (40 mm3, P = .003) and the contralateral side (29 mm3 P = .000). All patent bundles showed neovascularization extending into the cortical bone. Revascularized allografts had increased bone remodeling in the inner cortical area of the graft compared with the non-revascularized grafts (bone formation rate: 381 ± 60 µm3/µm3/year vs 299 ± 143 µm3/µm3/year, P = .05). In both the revascularized group and the control group, the bone formation rate exceed the contralateral side: In the revascularized grafts, the bone formation was 305% of contralateral side, and in the non-revascularized grafts, the bone formation was 179% of the contralateral side. There was no statistical significant difference in outer cortical bone formation between the revascularized and the non-revascularized allografts. Conclusion: Surgical revascularization of porcine tibial CBAs by implantation of an AV-bundle creates an enhanced autogenous neoangiogenic circulation and accelerates active bone formation.