Publikation: Facile construction of mechanically robust and highly osteogenic materials for bone regeneration
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National Natural Science Foundation of China: 32271421
National Natural Science Foundation of China: 82002275
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Hydrogel-based materials exhibit great potential in tissue engineering. However, their mechanical weakness limits applications in hard tissue regeneration, especially under load-bearing conditions. Although various strengthening strategies have been applied, the achieved mechanical response of hydrogels still lags behind the mechanics of natural bone. In this study, we present a novel mineralization approach to fabricate mechanically robust and highly osteogenic mineralized hydrogels. Cross-linking between deprotonated chains of poly(acrylic acid) (PAA) and divalent cations has led to formation of hydrogels with a compressive strength and elastic modulus of 0.3 ± 0.1 kPa and 1.3 ± 0.2 kPa, respectively. Subsequent in situ formation of nano-calcium hydroxide crystals remarkably increased the compressive strength and modulus to 7.9 ± 0.6 MPa and 339.3 ± 31.4 MPa, respectively, surpassing those of trabecular bone. Moreover, the mineralized hydrogels demonstrated remarkable osteogenic potential in vivo, exhibiting immunoregulatory activity, promoting early angiogenesis, and accelerating fracture healing at weeks 4 and 8. The mechanism of osteogenesis was further revealed by transcriptome sequencing, indicating that the mineralized hydrogels regulated the translation of extracellular matrix and biomineralization. Overall, our study presents a pioneering and cost-effective method for fabricating materials with exceptional mechanical strength and strong osteogenic properties, offering a promising avenue for load-bearing bone repair applications of hydrogel-based materials.
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CHEN, Song, Dachuan LIU, Qianping GUO, Li DONG, Huan WANG, Jiaxu SHI, Weicheng CHEN, Caihong ZHU, Helmut CÖLFEN, Bin LI, 2025. Facile construction of mechanically robust and highly osteogenic materials for bone regeneration. In: Materials Today Bio. Elsevier. 2025, 32, 101809. eISSN 2590-0064. Verfügbar unter: doi: 10.1016/j.mtbio.2025.101809BibTex
@article{Chen2025-06Facil-74037,
title={Facile construction of mechanically robust and highly osteogenic materials for bone regeneration},
year={2025},
doi={10.1016/j.mtbio.2025.101809},
volume={32},
journal={Materials Today Bio},
author={Chen, Song and Liu, Dachuan and Guo, Qianping and Dong, Li and Wang, Huan and Shi, Jiaxu and Chen, Weicheng and Zhu, Caihong and Cölfen, Helmut and Li, Bin},
note={Article Number: 101809}
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<dcterms:abstract>Hydrogel-based materials exhibit great potential in tissue engineering. However, their mechanical weakness limits applications in hard tissue regeneration, especially under load-bearing conditions. Although various strengthening strategies have been applied, the achieved mechanical response of hydrogels still lags behind the mechanics of natural bone. In this study, we present a novel mineralization approach to fabricate mechanically robust and highly osteogenic mineralized hydrogels. Cross-linking between deprotonated chains of poly(acrylic acid) (PAA) and divalent cations has led to formation of hydrogels with a compressive strength and elastic modulus of 0.3 ± 0.1 kPa and 1.3 ± 0.2 kPa, respectively. Subsequent in situ formation of nano-calcium hydroxide crystals remarkably increased the compressive strength and modulus to 7.9 ± 0.6 MPa and 339.3 ± 31.4 MPa, respectively, surpassing those of trabecular bone. Moreover, the mineralized hydrogels demonstrated remarkable osteogenic potential in vivo, exhibiting immunoregulatory activity, promoting early angiogenesis, and accelerating fracture healing at weeks 4 and 8. The mechanism of osteogenesis was further revealed by transcriptome sequencing, indicating that the mineralized hydrogels regulated the translation of extracellular matrix and biomineralization. Overall, our study presents a pioneering and cost-effective method for fabricating materials with exceptional mechanical strength and strong osteogenic properties, offering a promising avenue for load-bearing bone repair applications of hydrogel-based materials.</dcterms:abstract>
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