Nature-Inspired Hydrogel Network for Efficient Tissue-Specific Underwater Adhesive

Underwater adhesives with efficient, selective, and repeatable adhesion are urgently needed for biomedical applications. Catechol-containing hydrogel adhesives have aroused much interest, but the design of specific underwater adhesives to biotic surfaces is still a challenge. Here we report a facile way that recapitulates the adhesion mechanism of mussel and sea gooseberry for the development of robust and specific hydrogel adhesives. With an exquisite design of chemical bonding, catechol chemistry, and electrostatic interaction, the hydrogel consisting of poly(acrylic acid) grafted with N-hydroxysuccinimide ester (PAA-NHS ester), tea polyphenol (TP), chitosan (CS), and Al3+ exhibited fast, specific, and repeatable underwater adhesion to various biological tissues, such as porcine skin, intestine, liver, and shrimp. Furthermore, nanofibers-hydrogel composite (NF-HG) was prepared via the wicking effect of curcumin-loaded electrospun nanofibers. The NF-HG exhibited pH-responsive color changing properties, sustained drug release, and good cell viability, which made it suitable as a novel wound healing material. This strategy may provide great inspiration for designing multifunctional specific underwater adhesives.

Automated summary

Efficient, selective, and repeatable underwater adhesives are urgently needed for biomedical applications. By replicating the adhesion mechanism of mussels and sea gooseberries, a hydrogel adhesive with robust and specific adhesion to various biological tissues has been successfully developed. The use of catechol chemistry and electrostatic interaction in the design of the hydrogel contributes to its fast, specific, and repeatable underwater adhesion properties.