Programming fibril alignment and mechanical response in reconstituted collagen fibers using reagent-free biomimetic energetic electron crosslinking

Programming fibril alignment and mechanical response in reconstituted collagen fibers using reagent-free biomimetic energetic electron crosslinking

Due to its abundance in vertebrates, including humans, collagen is deemed to be a highly attractive bioderived material which bears large potential for cutting-edge applications in a variety of biomedical fields, including scaffolds, implantology, artificial organs, regenerative medicine and mechano...

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Bibliographic Details
Published in:Materials advances Vol. 5; no. 11; pp. 487 - 4817
Main Authors: Bublikova, Anastassiya, Schütte, Friedrich, Mayr, Stefan G
Format: Journal Article
Language:English
Published: 05-06-2024
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Summary:Due to its abundance in vertebrates, including humans, collagen is deemed to be a highly attractive bioderived material which bears large potential for cutting-edge applications in a variety of biomedical fields, including scaffolds, implantology, artificial organs, regenerative medicine and mechanobiology. Depending on structure, including hierarchical fibril alignment and crosslinking, in vivo collagen assemblies are characterized by Young's moduli ranging from some kPa to GPa. When heading for biomimicry of scaffolds and implants based on reconstituted collagen, control of mechanical response by fibril alignment and biomimetic crosslinking constitute central challenges. Within this work we demonstrate, that energetic electrons are a promising tool to permanently imprint prestrain-induced alignment of collagen fibrils within macroscopic collagen fibers by introduction of biomimetic crosslinks, resulting in elastic properties bridging orders of magnitude. High energy electron beam treatment is shown to permanently imprint prestrain-induced alignment of collagen fibrils within macroscopic collagen fibers by introduction of biomimetic crosslinks, bridging orders of magnitude in Young's moduli.
Bibliography:Electronic supplementary information (ESI) available. See DOI
https://doi.org/10.1039/d3ma01111a
ISSN:2633-5409
2633-5409
DOI:10.1039/d3ma01111a