Dolph Houben
170 CHAPTER 8 20. Larsen, M., P.F. Friedrich, and A.T. Bishop, A modified vascularized whole knee joint allotransplantation model in the rat. Microsurgery, 2010. 30 (7): p. 557-64. 21. Larsen, M., M. Pelzer, P.F. Friedrich, et al., Survival Of Microvascular Femoral Allograft Transplants By Surgical Angiogenesis Following Withdrawal Of Short-Term Post-Operative Immunosuppression. Journal of Bone & Joint Surgery - American Volume, Submitted for publication. 22. Larsen, M., M. Pelzer, P.F. Friedrich, et al., Living bone allotransplants survive by surgical angiogenesis alone: development of a novel method of composite tissue allotransplantation. Journal of Bone & Joint Surgery - American Volume, 2011. 93 (3): p. 261-73. 23. Larsen, M., W.F. Willems, M. Pelzer, et al., Augmentation of surgical angiogenesis in vascularized bone allotransplants with host-derived a/v bundle implantation, fibroblast growth factor-2, and vascular endothelial growth factor administration. Journal of Orthopaedic Research, 2010. 28 (8): p. 1015-21. 24. Pelzer, M., M. Larsen, Y.G. Chung, et al., Short-term immunosuppression and surgical neoangiogenesis with host vessels maintains long-term viability of vascularized bone allografts. Journal of Orthopaedic Research, 2007. 25 (3): p. 370-7. 25. Kotsougiani, D., C.A. Hundepool, L.F. Bulstra, et al., Recipient-derived angiogenesis with short term immunosuppression increases bone remodeling in bone vascularized composite allotransplantation: A pilot study in a swine tibial defect model. J Orthop Res., 2017. 35 (6): p. 1242-1249. doi: 10.1002/jor.23378. Epub 2016 Aug 12. 26. Giessler, G.A., M. Zobitz, P.F. Friedrich, et al., Host-derived neoangiogenesis with short-term immunosuppression allows incorporation and remodeling of vascularized diaphyseal allogeneic rabbit femur transplants. Journal of Orthopaedic Research, 2009. 27 (6): p. 763-70. 27. Giessler, G.A., M. Zobitz, P.F. Friedrich, et al., Transplantation of a vascularized rabbit femoral diaphyseal segment: mechanical and histologic properties of a new living bone transplantation model. Microsurgery, 2008. 28 (4): p. 291-9. 28. Chung, Y.G., A.T. Bishop, G.A. Giessler, et al., Surgical angiogenesis: a new approach to maintain osseous viability in xenotransplantation. Xenotransplantation, 2010. 17 (1): p. 38-47. 29. Ohno, T., M. Pelzer, M. Larsen, et al., Short-term survival of vascularized bone allotransplants: Host-derived vessel neoangiogenesis maintains bone blood flow after withdrawal of immunosuppression. Microsurgery, 2007. Accepted for publication . 30. Pelzer, M., M. Larsen, Y.-G. Chung, et al., Short-term immunosuppression and surgical neoangiogenesis with host vessels maintains long-term viability of vascularized bone allografts. Journal of Orthopaedic Research, 2007. 25 (3): p. 370-7. 31. Kuo, Y.-R., J.M. Sacks, W.P.A. Lee, et al., Porcine heterotopic composite tissue allograft transplantation using a large animal model for preclinical studies. Chang Gung Medical Journal, 2006. 29 (3): p. 268-74. 32. Kotsougiani, D., C.A. Hundepool, J.I.Willems, et al., Surgical Angiogenesis inPorcineTibial Allotransplantation: A New Large Animal Bone Vascularized Composite Allotransplantation Model. J Vis Exp., 2017. (126). (doi): p. 10.3791/55238. 33. Haughey, B.H. and W.R. Panje, A porcine model for multiple musculocutaneous flaps. Laryngoscope., 1989. 99 (2): p. 204-12. doi: 10.1288/00005537-198902000-00014.
Made with FlippingBook
RkJQdWJsaXNoZXIy ODAyMDc0