Bone tissue is a hierarchical material characterized at nanoscale by the mineralized collagen fibril, a recurring structure mainly composed of apatite minerals, collagen and water. Bone nanostructure has a fundamental role in determining the mechanical behavior of the tissue and its mass transport properties. Diffusion phenomenon allows to maintain an adequate supply of metabolites in the mechanisms of bone remodeling, adaptation and repair. Several analytical and computational models have been developed to analyze and predict bone tissue behavior. However, the fine replication of the natural tissue still represents a challenge. Insights on the structural organization at nanoscale and on the influence of apatite mineral crystals on the diffusion coefficient lead to outline the functional conditions for the development of biomimetic strategies for bone tissue engineering. Thorough understanding of bone nanostructure is essential to improve longevity of bioscaffolds and to decrease the risk of failure by controlling their mechanical and biological performance.

A nanostructured look of collagen apatite porosity into human mineralized collagen fibril / Bini, F; Pica, A; Marinozzi, A; Marinozzi, F. - In: BIOCELL. - ISSN 0327-9545. - 46:10(2022), pp. 2225-2229. [10.32604/biocell.2022.021150]

A nanostructured look of collagen apatite porosity into human mineralized collagen fibril

Pica, A;
2022-01-01

Abstract

Bone tissue is a hierarchical material characterized at nanoscale by the mineralized collagen fibril, a recurring structure mainly composed of apatite minerals, collagen and water. Bone nanostructure has a fundamental role in determining the mechanical behavior of the tissue and its mass transport properties. Diffusion phenomenon allows to maintain an adequate supply of metabolites in the mechanisms of bone remodeling, adaptation and repair. Several analytical and computational models have been developed to analyze and predict bone tissue behavior. However, the fine replication of the natural tissue still represents a challenge. Insights on the structural organization at nanoscale and on the influence of apatite mineral crystals on the diffusion coefficient lead to outline the functional conditions for the development of biomimetic strategies for bone tissue engineering. Thorough understanding of bone nanostructure is essential to improve longevity of bioscaffolds and to decrease the risk of failure by controlling their mechanical and biological performance.
2022
A nanostructured look of collagen apatite porosity into human mineralized collagen fibril / Bini, F; Pica, A; Marinozzi, A; Marinozzi, F. - In: BIOCELL. - ISSN 0327-9545. - 46:10(2022), pp. 2225-2229. [10.32604/biocell.2022.021150]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11388/342229
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