Thermodynamically Controlled Self‐Assembly of Hierarchically Staggered Architecture as an Osteoinductive Alternative to Bone Autografts

Osteoinductive synthetic biomaterials for replacing autografts can be developed by mimicking bone hierarchy and surface topography for host cell recruitment and differentiation. Until now, it has been challenging to reproduce a bone‐like staggered hierarchical structure since the energy change under...

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Bibliographic Details
Published in:Advanced functional materials 2019-03, Vol.29 (10), p.n/a
Main Authors: Liu, Yan, Luo, Dan, Yu, Min, Wang, Yu, Jin, Shanshan, Li, Zixin, Cui, Shengjie, He, Danqing, Zhang, Ting, Wang, Tie, Zhou, Yanheng
Format: Article
Language:English
Subjects:
Architecture
Biocompatibility
Biological activity
Biomedical materials
Blood vessels
Bone marrow
bone organ formation
Homing
Materials science
Mineralization
Morphology
osteoinduction
Polyacrylic acid
Recruitment
self‐assembly
staggered nanotopography
Stem cells
Structural hierarchy
thermodynamic control
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Summary:Osteoinductive synthetic biomaterials for replacing autografts can be developed by mimicking bone hierarchy and surface topography for host cell recruitment and differentiation. Until now, it has been challenging to reproduce a bone‐like staggered hierarchical structure since the energy change underlying synthetic pathways in vitro is essentially different from that of the natural process in vivo. Herein, a bone‐like hierarchically staggered architecture is reproduced under thermodynamic control involving two steps: fabrication of a high‐energy polyacrylic acid‐calcium intermediate and selective mineralization in collagenous gap regions driven by an energetically downhill process. The intermediate energy interval could easily be adjusted to determine different mineralization modes, with distinct morphologies and biofunctions. Similar to bone autografts, the staggered architecture offers a bone‐specific microenvironment for stem cell recruitment and multidifferentiation in vitro, and induces neo‐bone formation with bone marrow blood vessels by host stem cell homing in vivo. This work provides a novel perspective for an in vitro simulating biological mineralization process and proof of concept for the clinical application of smart biomaterials. A bone‐like hierarchically staggered nanostructure is reproduced in vitro under thermodynamic control, in which a high‐energy intermediate selectively transports calcium ions into collagenous gap regions via an energetically downhill process. The staggered architecture offers a bone‐specific microenvironment for cell homing and multidifferentiation, andinduces endogenous bone regeneration with structural and functional characteristics similar to native bone/marrow.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201806445