1 research outputs found
Mechanically Durable and Biologically Favorable Protein Hydrogel Based on Elastic Silklike Protein Derived from Sea Anemone
As
biodegradable scaffolds, protein hydrogels have considerable
potential, particularly for bioartificial organs and three-dimensional
space-filling materials. However, their low strength and stiffness
have been considered to be limitations for enduring physiological
stimuli. Therefore, protein hydrogels have been commonly utilized
as delivery vehicles rather than as supporting materials. In this
work, sea anemone tentacle-derived recombinant silk-like protein (aneroin)
was evaluated as a potential material for a mechanically durable protein
hydrogel. Inspired by the natural hardening mechanism, photoinitiated
dityrosine cross-linking was employed to fabricate an aneroin hydrogel.
It was determined that the fabricated aneroin hydrogel was approximately
10-fold stiffer than mammalian cardiac or skeletal muscle. The aneroin
hydrogel provided not only structural support but also an adequate
environment for cells. It exhibited an adequate swelling ability and
microstructure, which are beneficial for facilitating mass transport
and cell proliferation. Based on its mechanical and biological properties,
this aneroin hydrogel could be used in various biomedical applications,
such as cell-containing patches, biomolecule carriers, and artificial
extracellular matrices