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Hydroxyapatite-Tethered Peptide Hydrogel Promotes Osteogenesis

Hongwen Yu, Jiaqi Song, Xianpeng Zhang, Kuo Jiang, Fan Hong, Yibing Li, Yuan-Ting Zhao, Shichang Liu, Dingjun Hao, Guanying Li

2022Gels13 citationsDOIOpen Access PDF

Abstract

Hydroxyapatite (HAp) as natural bone composition is highly osteoinductive. To harvest its osteoinductivity in bone regenerative engineering, the HAp-supporting hydrogel is urgently needed to minimize inhomogeneous aggregation of HAp. Here, we developed a HAp-stabilizing hydrogel based on peptide self-assembly. FmocFFRR was efficient for HAp-capping due to arginine-phosphate interaction. Tethering FmocFFRR on the HAp surface facilitated self-assembly to form FmocFFRR/HAp hybrid hydrogel, enabling stable dispersion of HAp in it. The molecular interactions between FmocFFRR and HAp particles were studied using microscopic and spectral characterizations. FmocFFRR/HAp hydrogel exhibited more enhanced mechanical properties than FmocFFRR. The biocompatibility of FmocFFRR/HAp hydrogel was verified using an ATP assay and live-dead staining assay. More importantly, FmocFFRR/HAp hydrogel not only enabled cell attachment on its surface, but also supported 3D cell culturing inside the hydrogel. Further, 3D culturing of MC3T3-E1 preosteoblasts inside FmocFFRR/HAp hydrogel significantly enhanced the expressions of osteogenesis markers, including alkaline phosphate (ALP), type-I collagen (COL1), and osteocalcin (OCN), demonstrating the promoting effect of osteoblast differentiation. These findings inspire its potential application in bone regenerative engineering.

Topics & Concepts

BiocompatibilityOsteoblastOsteocalcinSelf-healing hydrogelsChemistryTissue engineeringRegenerative medicineBiophysicsNanotechnologyMaterials scienceAlkaline phosphataseBiomedical engineeringCellBiochemistryIn vitroPolymer chemistryMedicineBiologyOrganic chemistryEnzymeSupramolecular Self-Assembly in MaterialsBone Tissue Engineering MaterialsBone and Dental Protein Studies