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Hydroxyapatite formation in biomimetic synthesis with the interface of a pDA@SIS membrane

Qiuhong Zhu, Hua Jiao, Xiaoliang Zhao, Yufei Tang, Kang Zhao, Xingchun Gou

2022RSC Advances14 citationsDOIOpen Access PDF

Abstract

ionic diffusion to generate supersaturation reaction conditions in 1-14 days. The system can successfully obtain polycrystals with low crystallinity on the pDA-collagen complex template surface of collagen fibers and along the collagen fibers. It initiates a generalized bionic mineralization pathway which can reduce the nucleation interfacial energy to promote rapid hydroxyapatite (HAP) nucleation and crystallization and accelerate the rate of collagen fiber mineralization. The pDA@SIS mineralized collagen membrane shows good biocompatibility with 100% cellular activity in the CCK-8 test, which significantly improved the adhesion proliferation of MC3T3-E1 cells. The pDA-SIS collagen complex, as a new type of mineralization template, may propose a new collagen mineralization strategy to produce a mineralized pDA@SIS scaffold bone-like material for tissue engineering or can potentially be applied in bone repair and regeneration.

Topics & Concepts

Interface (matter)MembraneMaterials scienceChemical engineeringChemistryNanotechnologyEngineeringComposite materialBiochemistryCapillary actionCapillary numberBone Tissue Engineering Materialsbiodegradable polymer synthesis and properties3D Printing in Biomedical Research
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