BACKGROUND: Bone grafts, allografts, and biocompatible artificial bone substitutes all have their shortcomings when used for the repair of cranial bone defects. Tissue engineered bone shows promise as an alternative for the repair of these defects. MATERIALS AND METHODS: Rabbit bone marrow mesenchymal stromal cells (MSCs) were separated from iliac crest aspirates and expanded in a monolayer culture 1 month before implantation. These MSCs were then infected with replication-defective adenovirus-human BMP-2 genes 1 week before implantation. Bilateral critical-size cranial defects were created in the animal with removal of osteoinductive periosteum and dura. MSCs were mixed with alginate UP (ultrapure) to form MSC/polymer construct. MSCs used for the control site were infected with adenovirus beta-galactosidase (beta-gal). After 1 week, 6 weeks, and 3 months, five rabbits from each experimental group were sacrificed and the cranial defect site was examined by histology study. RESULTS: Near-complete repair of the large size cranial defects using the tissue engineered MSC/alginate construct was observed. The H&E stain and von Kossa's staining should better regenerate bone at the experiment site. A statistically significant difference in bone formation was noted by 3D CT imaging at 3 months post-BMP-2 treatment of the cranial defects (0.79 +/- 0.06 versus 0.47 +/- 0.05 cm(2), P < 0.001) but not at 6 weeks (0.36 +/- 0.04 versus 0.33 +/- 0.03 cm(2), P = 0.347). CONCLUSIONS: Near-complete repair of large cranial defects can be achieved using tissue engineered bone. The use of newly developed polymers as well as the integration of the stem cell concept with gene medicine is necessary to attain this goal.
BACKGROUND: Bone grafts, allografts, and biocompatible artificial bone substitutes all have their shortcomings when used for the repair of cranial bone defects. Tissue engineered bone shows promise as an alternative for the repair of these defects. MATERIALS AND METHODS:Rabbit bone marrow mesenchymal stromal cells (MSCs) were separated from iliac crest aspirates and expanded in a monolayer culture 1 month before implantation. These MSCs were then infected with replication-defective adenovirus-humanBMP-2 genes 1 week before implantation. Bilateral critical-size cranial defects were created in the animal with removal of osteoinductive periosteum and dura. MSCs were mixed with alginate UP (ultrapure) to form MSC/polymer construct. MSCs used for the control site were infected with adenovirus beta-galactosidase (beta-gal). After 1 week, 6 weeks, and 3 months, five rabbits from each experimental group were sacrificed and the cranial defect site was examined by histology study. RESULTS: Near-complete repair of the large size cranial defects using the tissue engineered MSC/alginate construct was observed. The H&E stain and von Kossa's staining should better regenerate bone at the experiment site. A statistically significant difference in bone formation was noted by 3D CT imaging at 3 months post-BMP-2 treatment of the cranial defects (0.79 +/- 0.06 versus 0.47 +/- 0.05 cm(2), P < 0.001) but not at 6 weeks (0.36 +/- 0.04 versus 0.33 +/- 0.03 cm(2), P = 0.347). CONCLUSIONS: Near-complete repair of large cranial defects can be achieved using tissue engineered bone. The use of newly developed polymers as well as the integration of the stem cell concept with gene medicine is necessary to attain this goal.
Authors: Brent R Weil; Mariuxi C Manukyan; Jeremy L Herrmann; Aaron M Abarbanell; Jeffrey A Poynter; Yue Wang; Daniel R Meldrum Journal: J Surg Res Date: 2010-08-06 Impact factor: 2.192
Authors: Stephan T Becker; Timothy Douglas; Yahya Acil; Hermann Seitz; Sureshan Sivananthan; Jörg Wiltfang; Patrick H Warnke Journal: J Mater Sci Mater Med Date: 2010-02-07 Impact factor: 3.896
Authors: Zarana S Patel; Simon Young; Yasuhiko Tabata; John A Jansen; Mark E K Wong; Antonios G Mikos Journal: Bone Date: 2008-07-14 Impact factor: 4.398
Authors: Spyros G Pneumaticos; Georgios K Triantafyllopoulos; Efthimia K Basdra; Athanasios G Papavassiliou Journal: J Cell Mol Med Date: 2010-11 Impact factor: 5.310