posted on 2018-07-17, 00:00authored byLan Jiang, Chang Liu, Koichi Mayumi, Kazuaki Kato, Hideaki Yokoyama, Kohzo Ito
Gels
with high mechanical performance have attracted great interest
because of their potential biomedical applications. Tough gels reported
thus far usually contain sacrificial species to dissipate energy,
thus compromising the fatigue resistance. In this study, highly stretchable
and recoverable gels can be achieved by cross-linking cyclodextrin
(CD)-based polyrotaxane with a low host coverage, synthesized via
a one-pot enzymatic end-capping reaction with 90% yield and ∼2%
CD coverage (PR02). The low coverage allows the CD cross-links to
freely slip on the axis over large distance (∼2/3 of the axis
length) and thus allows the PR02 slide-ring network keep intact under
large deformation via the pulley effect. The PR02-hydrogel can be
stretched up to ∼1600% long, withstand ∼1 MPa stress,
and fully recover instantly. PR02-DMSO gels exhibit a shape memory
behavior that withstood large deformation. As the first research to
control the final property of the network by precisely controlling
the slide distance of the cross-links, this work not only pushes the
performance envelope of soft matters but also opens new opportunities
for designing tough materials.