Compressive stress improves mechanical properties of mineralized collagen by dynamically regulating its mineralization - a closed-loop regulation mechanism

[Display omitted] •Mechanical stimulation can significantly improves the mechanical properties of mineralized collagen;•Improved mechanical properties by optimizes the structure of mineralized collagen;•Mechanical properties of mineralized collagen provide feedback on internal stress distribution, s...

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Bibliographic Details
Published in:Materials & design 2024-03, Vol.239, p.112830, Article 112830
Main Authors: Niu, Yumiao, Chen, Jiawen, Geng, Ziyao, Wu, Wei, Cai, Hefang, Liu, Chenxin, Cao, Peng, Zhang, Yanping, Liu, Youjun, Qiao, Aike, Du, Tianming
Format: Article
Language:English
Subjects:
Biomineralization
Mechanical property
Mechano-regulatory
Multi-morphology
Multiscale modelling
Stress distribution
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Summary:[Display omitted] •Mechanical stimulation can significantly improves the mechanical properties of mineralized collagen;•Improved mechanical properties by optimizes the structure of mineralized collagen;•Mechanical properties of mineralized collagen provide feedback on internal stress distribution, subsequently impacting mineralization structure.•Simulating collagen mineralization process. Mineralized collagen scaffold is one of the best choices for bone defects treatment, but weak mechanical strength is the main factor restricting its development. Recent studies demonstrated that despite being a fundamental form of mechanical stimulation in human activities, the impact of cyclic compressive stress on collagen mineralization remains unclear, with even less known about the dynamic mechanical mechanism. This study employed cyclic compressive stress to investigate its effect on collagen mineralization. The findings revealed that cyclic compressive strain promotes collagen mineralization by facilitating increased mineral penetration into the collagen and altering mineral morphology on the collagen surface. As the mineral volume fraction of mineralized collagen rises, its elastic modulus also increases. Additionally, the finite element simulation results proved that cyclic compressive stress can impact mineral distribution by affecting their transport and deposition, consequently influencing the stress distribution and regulating mechanical properties of mineralized collagen. Alterations in mechanical properties provide feedback on internal stress distribution, subsequently impacting mineral mineralization. This study achieves a closed-loop study on the mechanical regulated collagen mineralization, offers insight into the mechanism of collagen mineralization, paving the way for further exploration of biomineralization mechanisms and potentially inspiring novel approaches for the fabrication of mineralized collagen scaffolds.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2024.112830