posted on 2018-07-16, 00:00authored byYongsan Li, Xing Wang, Ya-nan Fu, Yen Wei, Lingyun Zhao, Lei Tao
Smart materials that
can respond to multistimuli have been broadly
studied. However, the smart materials that can spontaneously answer
the ever-changing inner environment of living bodies have not been
reported. Here, we report a strategy based on the dynamic chemistry
to develop possible self-adapting solid materials that can automatically
change shape without external stimuli, as organisms do. The self-adapting
property of a chitosan-based self-healing hydrogel has been rediscovered
since its dynamic Schiff-base network confers the unique mobility
to that solid gel. As a result, the hydrogel can move slowly, like
an octopus climbing through a narrow channel, only following the natural
forces of surface tension and gravity. The fascinating self-adapting
feature enables this hydrogel as an excellent drug carrier for the
in vivo wound treatment. In a healing process of the rat-liver laceration,
this self-adapting hydrogel demonstrated remarkable superiority over
traditional drug delivery methods, suggesting the great potential
of this self-adapting hydrogel as a promising new material for biomedical
applications. We believe the current research revealed a possible
strategy to achieve self-adapting materials and may pave the way toward
the further development, study, and application of new-generation
smart materials.