再生(生物学)
牙科
牙髓干细胞
牙槽
牙髓(牙)
细胞生物学
干细胞
牙周纤维
医学
牙本质
生物
口腔正畸科
牙骨质
作者
Hao Guo,Bei Li,Meiling Wu,Wanmin Zhao,Xiaoning He,Bing‐Dong Sui,Zhiwei Dong,Ling Wang,Songtao Shi,Xiaoyao Huang,Xuemei Liu,Zihan Li,Xiaohe Guo,Kun Xuan,Yan Jin
出处
期刊:Biomaterials
[Elsevier]
日期:2021-12-01
卷期号:279: 121223-121223
被引量:35
标识
DOI:10.1016/j.biomaterials.2021.121223
摘要
Harnessing developmental processes for tissue engineering represents a promising yet challenging approach to regenerative medicine. Tooth avulsion is among the most serious traumatic dental injuries, whereas functional tooth regeneration remains uncertain. Here, we established a strategy using decellularized tooth matrix (DTM) combined with human dental pulp stem cell (hDPSC) aggregates to simulate an odontogenesis-related developmental microenvironment. The bioengineered teeth reconstructed by this strategy regenerated three-dimensional pulp and periodontal tissues equipped with vasculature and innervation in a preclinical pig model after implantation into the alveolar bone. These results prompted us to enroll 15 patients with avulsed teeth after traumatic dental injuries in a pilot clinical trial. At 12 months after implantation, bioengineered teeth led to the regeneration of functional teeth, which supported continued root development, in humans. Mechanistically, exosomes derived from hDPSC aggregates mediated the tooth regeneration process by upregulating the odontogenic and angiogenic ability of hDPSCs. Our findings suggest that odontogenic microenvironment engineering by DTM and stem cell aggregates initiates functional tooth regeneration and serves as an effective treatment for tooth avulsion.
科研通智能强力驱动
Strongly Powered by AbleSci AI