Maxillofacial and periodontal tissue-engineered bone:vascularization and osteogenesis strategies
10.3969/j.issn.2095-4344.2015.42.018
- VernacularTitle:颌面部及牙周组织工程骨的血管化和成骨策略
- Author:
Xinyue ZHANG
;
Yan LI
;
Chenjun LI
- Publication Type:Journal Article
- From:
Chinese Journal of Tissue Engineering Research
2015;(42):6819-6825
- CountryChina
- Language:Chinese
-
Abstract:
BACKGROUND:Maxilofacial bone and periodontal tissue defect is one of the important diseases that affect human functionality and aesthetic appearance, and bone tissue engineering becomes the main means to repair maxilofacial and periodontal tissue defects. Currently, the basic mode is constructed by the combination of co-culture of seed cels and cels, scaffolds and micro-environment. Pre-vascularization and rapid osteogenesis of tissue-engineered bone can reduce implant necrosis and absorption, and improve repair success rate. OBJECTIVE:To summarize the new progress of bone tissue engineering used in the oral and maxilofacial and periodontal tissue in the past 5 years. METHODS:CNKI database and PubMed database from 2010 to 2015 were searched using the keywords of “oral and maxilofacial, bone tissue engineering, bone regeneration, vascularization, genetic modification, seed cels, support material, microenvironment” in Chinese and English, respectively. After elimination of independent and repetitive studies, 68 articles were included in result analysis. RESULTS AND CONCLUSION: The tissue-engineered bone has achieved tremendous progress in the repair of oral and maxilofacial and periodontal tissue defects. The three-dimensional scaffold with gene-modified seed cels can effectively promote the vascularization, improve the osteogenic effect and increased the probability of success in mandibular defect repair. In addition, tissue-engineered bone implantation into the alveolar ridge defects or fresh extraction fossa can effectively restore and preserve alveolar ridge height and width, to ensure a good bone condition for subsequent restorative treatment. After the implantation of tissue-engineered bone, different external environmental stimuli could be loaded at defect sites, and the extracelular matrix components or signal pathway could be adjusted to change the process of vascularization. Vascularization is a premise condition for the establishment of an effective blood circulation to ensure the success of scaffold implantation.
