Yen-Hong Lin

TL;DR: Results indicate the CS/PCL composite exhibited a favorable bioactivity and osteoconductive properties that could be served as a promising biomaterial for bone tissue engineering scaffolds.

TL;DR: This work presented a promising technique for producing bioscaffolds that can augment bone tissue regeneration in numerous aspects and exhibited excellent biocompatibility and effectively enhanced cellular adhesion, proliferation, and differentiation of human Wharton’s Jelly mesenchymal stem cells by increasing the expression of osteogenic-related genes.

TL;DR: 3D-printed GCP scaffolds own the dual bioactivities to reach the osteogenesis and vascularization for bone regeneration and infers that the G CP scaffold could induce the effects of proliferation, differentiation and related protein expression on WJMSCs through FGFR pathway.

TL;DR: 3D MesoCS/PCL porous scaffolds were successfully fabricated via a 3D printing system and were found to show good cellular activity for cell behavior although the PL method was not favorable for clinical application in relation with the preservation of BMP-2.

TL;DR: It was shown that 3D printed Sr CS scaffolds with specific controllable structures can be fabricated and SrCS scaffolds had enhanced mechanical property and osteogenesis behavior which makes it a suitable potential candidate for bone regeneration.