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Tissue Engineering
Stem Cells Associated with Macroporous Bioceramics for Long Bone Repair: 6- to 7-Year Outcome of a Pilot Clinical Study
To cite this article:
Maurilio Marcacci, Elizaveta Kon, Vladimir Moukhachev, Andrei Lavroukov, Sergej Kutepov, Rodolfo Quarto, Maddalena Mastrogiacomo, Ranieri Cancedda.
Tissue Engineering.
May 2007,
13(5): 947-955.
doi:10.1089/ten.2006.0271.
Maurilio Marcacci, M.D.Istituti Ortopedici Rizzoli, Bologna, Italy. Elizaveta Kon, M.D.Istituti Ortopedici Rizzoli, Bologna, Italy. Vladimir Moukhachev, M.D.Ural Orthopedic Research Institute, Ekaterinburg, Russia. Andrei Lavroukov, M.D.Ural Orthopedic Research Institute, Ekaterinburg, Russia. Sergej Kutepov, M.D.Ural State Medical Academy, Ekaterinburg, Russia. Rodolfo Quarto, M.D.Dipartimento di Oncologia Biologia e Genetica, Universita’ di Genova & Istituto Nazionale per la Ricerca sul Cancro, Genova, Italy. Maddalena Mastrogiacomo, Ph.D.Dipartimento di Oncologia Biologia e Genetica, Universita’ di Genova & Istituto Nazionale per la Ricerca sul Cancro, Genova, Italy. Ranieri Cancedda, M.D.Dipartimento di Oncologia Biologia e Genetica, Universita’ di Genova & Istituto Nazionale per la Ricerca sul Cancro, Genova, Italy. Extensive bone loss is still a major problem in orthopedics. A number of different therapeutic approaches have been developed and proposed, but so far none have proven to be fully satisfactory. We used a new tissue engineering approach to treat four patients with large bone diaphysis defects and poor therapeutic alternatives. To obtain implantable three-dimensional (3D) living constructs, cells isolated from the patients' bone marrow stroma were expanded in culture and seeded onto porous hydroxyapatite (HA) ceramic scaffolds designed to match the bone deficit in terms of size and shape. During the surgical session, an Ilizarov apparatus or a monoaxial external fixator was positioned on the patient's affected limb and the ceramic cylinder seeded with cells was placed in the bone defect. Patients were evaluated at different postsurgery time intervals by conventional radiographs and computed tomography (CT) scans. In one patient, an angiographic evaluation was performed at 6.5 years follow-up. In this study we analyze the long-term outcome of these patients following therapy. No major complications occurred in the early or late postoperative periods, nor were major complaints reported by the patients. No signs of pain, swelling, or infection were observed at the implantation site. Complete fusion between the implant and the host bone occurred 5 to 7 months after surgery. In all patients at the last follow-up (6 to 7 years postsurgery in patients 1 to 3), a good integration of the implants was maintained. No late fractures in the implant zone were observed. The present study shows the long-term durability of bone regeneration achieved by a bone engineering approach. We consider the obtained results very promising and propose the use of culture-expanded osteoprogenitor cells in conjunction with porous bioceramics as a real and significant improvement in the repair of critical-sized long bone defects.  This paper was cited by:A bioactive triphasic ceramic‐coated hydroxyapatite promotes proliferation and osteogenic differentiation of human bone marrow stromal cells Manitha B. Nair, Anne Bernhardt, Anja Lode, Christiane Heinemann, Sebastian Thieme, Thomas Hanke, Harikrishna Varma, Michael Gelinsky, Annie John Journal of Biomedical Materials Research Part A. Sep 2009, Vol. 90A, No. 2: 533-542 CrossRef Major bone defect treatment with an osteoconductive bone substitute Stefania Paderni, S. Terzi, L. Amendola MUSCULOSKELETAL SURGERY. Jul 2009 CrossRef Feasibility, tailoring and properties of polyurethane/bioactive glass composite scaffolds for tissue engineering Francesco Baino, Enrica Verné, Chiara Vitale-Brovarone Journal of Materials Science: Materials in Medicine. 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Feb 2009: n/a-n/a CrossRef Development of sarcomas in mice implanted with mesenchymal stem cells seeded onto bioscaffolds R. Tasso, A. Augello, M. Carida', F. Postiglione, M. G. Tibiletti, B. Bernasconi, S. Astigiano, F. Fais, M. Truini, R. Cancedda, G. Pennesi Carcinogenesis. Oct 2008, Vol. 30, No. 1: 150-157 CrossRef Use of autologous bone marrow mononuclear cells and cultured bone marrow stromal cells in dogs with orthopaedic lesions A. Crovace, A. Favia, L. Lacitignola, M. S. Comite, F. Staffieri, E. Francioso Veterinary Research Communications. Oct 2008, Vol. 32, No. S1: 39-44 CrossRef Application of stem cells in bone repair Elaine Y. L. Waese, Rita R. Kandel, William L. Stanford Skeletal Radiology. Aug 2008, Vol. 37, No. 7: 601-608 CrossRef Mesenchymal cells for skeletal tissue engineering Bethany J Slater, Matthew D Kwan, Deepak M Gupta, Nicholas J Panetta, Michael T Longaker Expert Opinion on Biological Therapy. Aug 2008, Vol. 8, No. 7: 885-893 CrossRef Updates on stem cells and their applications in regenerative medicine Stefan Bajada, Irena Mazakova, James B. Richardson, Nureddin Ashammakhi Journal of Tissue Engineering and Regenerative Medicine. Jul 2008, Vol. 2, No. 4: 169-183 CrossRef Microcomputed tomography imaging in a rat model of delayed union/non-union fracture G.R. Dickson, C. Geddis, N. Fazzalari, D. Marsh, I. Parkinson Journal of Orthopaedic Research. Jun 2008, Vol. 26, No. 5: 729-736 CrossRef Porous Poly(Lactic-Co-Glycolic Acid) Microsphere as Cell Culture Substrate and Cell Transplantation Vehicle for Adipose Tissue Engineering Sun-Woong Kang, Sang-Woo Seo, Cha Yong Choi, Byung-Soo Kim Tissue Engineering Part C: Methods. Mar 2008, Vol. 14, No. 1: 25-34 Abstract | Full Text PDF | Reprints & Permissions |
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