posted on 2020-12-24, 20:04authored byLin Wang, Feiyu Wang, Bo Xu, Man Zhou, Yuanyuan Yu, Ping Wang, Qiang Wang
Pure
silk fibroin (SF) hydrogel exhibits poor elasticity and low
water retention ability, owing to the compact crystalline structure
and high content of hydrophobic amino acids. Herein, a composite double-network
hydrogel of SF and tyramine-modified hyaluronic acid (mHA) was constructed,
via the laccase-catalyzed coupling reactions between the phenolic
hydroxyl groups from SF and mHA chains. The obtained hydrogel exhibits
improved structural stability and flexibility compared to pure SF
hydrogel. Meanwhile, the swelling ratio, mechanical property, drug
loading, and release behaviors can be readily regulated by alcoholization,
altering pH value, and ionic strength of soaking solutions. Increasing
pH values promoted the swelling capacity of SF/mHA hydrogel, resulting
in an efficient loading of cationic drugs and sustained release of
anionic drugs as well. The addition of inorganic salts reduced electrostatic
repulsion in the hydrogel scaffold, accompanying with a noticeable
improvement of toughness. Furthermore, alcohol treatment induced conformation
changes of fibroin protein, and the composite hydrogel achieved a
higher fracture and improved elasticity. The present work provides
a biological alternative to regulate the mechanical behavior, drug
loading, and sustained release capacity of the SF-based hydrogel.