Spherulitic Crystal Growth Drives Mineral Deposition Patterns in Collagen‐Based Materials

The formation of the hard tissues that provide support and mobility to organisms is achieved through the interplay of inorganic crystals and an organic framework composed of collagen and a small percentage of non‐collagenous proteins. Despite their clinical relevance, the mechanisms governing minera...

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Bibliographic Details
Published in:Advanced functional materials 2022-08, Vol.32 (31), p.n/a
Main Authors: Macías‐Sánchez, Elena, Tarakina, Nadezda V., Ivanov, Danail, Blouin, Stéphane, Berzlanovich, Andrea M., Fratzl, Peter
Format: Article
Language:English
Subjects:
3D electron microscopy
bone mineralization
Collagen
collagen mineralization
Crystal growth
Crystallites
Crystals
energy dispersive X‐ray spectroscopy
Materials science
Mineralization
Proteins
Spherulites
transmission electron microscopy
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Summary:The formation of the hard tissues that provide support and mobility to organisms is achieved through the interplay of inorganic crystals and an organic framework composed of collagen and a small percentage of non‐collagenous proteins. Despite their clinical relevance, the mechanisms governing mineralization of the extracellular matrix are still poorly understood. By using 3D electron tomography and high‐resolution electron microscopy imaging and spectroscopy, it has been demonstrated that mineralization proceeds through a spherulitic‐like crystal growth process. First, aggregates of disordered crystals form in the interfibrillar spaces, which lead to the mineralization of adjacent fibrils. Mineral propagates steadily through the inter‐ and intrafibrillar spaces of the collagen structure forming layered spherulites that grow to confluence. The structure of the collagen fibrils serves as a protein scaffold to guide the formation of a myriad of platelet‐shaped crystallites that make up each of these spherulites. At their periphery, nanosized unmineralized areas remain, leading to the formation of the characteristic lacy pattern observed in the transversal cross‐section of mature calcified tissues. This study provides fundamental insights into the bone formation process and represents a potential strategy for complex materials design. Mineral propagates following a spherulitic growth process, following the protein scaffold provided by collagen fibrils. These spherulites exhibit a curved‐layered structure that contains a multitude of mineral platelets. Nanosized spaces remain unmineralized within the fibril, likely determined by the presence of macromolecular complexes, giving rise to the characteristic lacy pattern observed in transversal cross‐section.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202200504