Bio-design material as scaffold module proposed to surgical application in osteoarthritis: fabrication, characterization, biological evaluation of in vitro testing.
Atsadaporn Thangprasert, Anne Bernhardt, Elke Gossla, David Kilian, Saranyoo Klaiklay, Jirut Meesane, Papitchaya Srithep, Michael Gelinsky, Pakorn Pasitsuparoad
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引用次数: 0
Abstract
Treatment of osteochondral defects is a major topic of current research and becomes more important in an aging society. The challenges in bone and cartilage repair arise from structure and function of these different tissues. This study proposes a biphasic model combining cartilage and bone scaffolds based on silk fibroin (SF) biopolymers. For cartilage phase, SF scaffolds were coated with gelatin and/or agarose layers. For bone scaffolds, mineralized collagen solutions were coated on or mixed into the SF matrix. The physical and biological properties of these samples were evaluated to find the optimum conditions for a biphasic scaffold. Modification of both cartilage and bone scaffolds resulted in smaller pore size, lower swelling rate and higher rigidity. Gelatin significantly promoted cartilage biomarker production and agarose facilitated cell proliferation, inducing a homogenous cell distribution, and stimulating chondrogenesis. Furthermore, modification with mineralized collagen decreased cell proliferation in osteoblast progenitors but enhanced differentiation into osteoblasts. The optimum conditions were found at a mixture of gelatin and agarose for coating in case of cartilage phase and low mineralized collagen content for bone phase.
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