Leveraging advances in biology to design biomaterials

Biomaterials have dramatically increased in functionality and complexity, allowing unprecedented control over the cells that interact with them. From these engineering advances arises the prospect of improved biomaterial-based therapies, yet practical constraints favour simplicity. Tools from the bi...

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Veröffentlicht in:Nature materials 2017-12, Vol.16 (12), p.1178-1185
Hauptverfasser: Darnell, Max, Mooney, David J.
Format: Artikel
Sprache:eng
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Zusammenfassung:Biomaterials have dramatically increased in functionality and complexity, allowing unprecedented control over the cells that interact with them. From these engineering advances arises the prospect of improved biomaterial-based therapies, yet practical constraints favour simplicity. Tools from the biology community are enabling high-resolution and high-throughput bioassays that, if incorporated into a biomaterial design framework, could help achieve unprecedented functionality while minimizing the complexity of designs by identifying the most important material parameters and biological outputs. However, to avoid data explosions and to effectively match the information content of an assay with the goal of the experiment, material screens and bioassays must be arranged in specific ways. By borrowing methods to design experiments and workflows from the bioprocess engineering community, we outline a framework for the incorporation of next-generation bioassays into biomaterials design to effectively optimize function while minimizing complexity. This framework can inspire biomaterials designs that maximize functionality and translatability. Advances in biomaterials have enabled control over desired cell responses. Here, the authors highlight key analytical and bioprocessing techniques, outlining a framework for incorporating these tools into designing functionally optimal biomaterials.
ISSN:1476-1122
1476-4660
DOI:10.1038/nmat4991