The synergistic effects of graphene-contained 3D-printed calcium silicate/poly-ε-caprolactone scaffolds promote FGFR-induced osteogenic/angiogenic differentiation of mesenchymal stem cells

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题名:	The synergistic effects of graphene-contained 3D-printed calcium silicate/poly-ε-caprolactone scaffolds promote FGFR-induced osteogenic/angiogenic differentiation of mesenchymal stem cells
作者:	Lin, Yen-Hong;Lin, Yen-Hong;Chua, Tsan-Yu;Chuang, Tsan-Yu;Chi, Wei-Hung;Chiang, Wei-Hung;Peter, I-Wen;Chen, I-Wen Peter;Wang, Kan;Wang, Kan;謝明佑;Shie, Ming-You;陳怡文;Chen, Yi-Wen
贡献者:	生物資訊與醫學工程學系
关键词:	Graphene;Calcium silicate;3D print;Osteogenesis;Angiogenesis;Fibroblast growth factor receptor
日期:	2019-11
上传时间:	2020-09-02 08:05:44 (UTC+0)
出版者:	亞洲大學
摘要:	Graphene-contained calcium silicate (CS)/polycaprolactone (PCL) scaffold (GCP) provides an alternative solution that can bring several bone formation properties, such as osteoinductive. This study finds out the optimal percentage of graphene additive to calcium silicate and polycaprolactone mixture for excellent in vitro and in vivo bone-regeneration ability, in addition, this scaffold could fabricate by 3D printing technology and demonstrates distinct mechanical, degradation, and biological behavior. With controlled structure and porosity by 3D printing, osteogenesis and proliferation capabilities of Wharton's Jelly derived mesenchymal stem cells (WJMSCs) were significantly enhanced when cultured on 3D printed GCP scaffolds. In this study, it was also discovered that fibroblast growth factor receptor (FGFR) plays an active role in modulating differentiation behavior of WJMSCs cultured on GCP scaffolds. The validation has been proved by analyzed the decreased cell proliferation, osteogenic-related protein (ALP and OC), and angiogenic-related protein (VEGF and vWF) with FGFR knockdown on all experimental groups. Moreover, this study infers that the GCP scaffold could induce the effects of proliferation, differentiation and related protein expression on WJMSCs through FGFR pathway. In summary, this research indicated the 3D-printed GCP scaffolds own the dual bioactivities to reach the osteogenesis and vascularization for bone regeneration.
關聯:	Materials Science & Engineering C-Materials for Biological Applications
显示于类别:	[生物資訊與醫學工程學系 ] 期刊論文

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