posted on 2014-05-14, 00:00authored byMingyu Guo, Louis M. Pitet, Hans M. Wyss, Matthijn Vos, Patricia Y. W. Dankers, E. W. Meijer
Hydrogels were prepared with physical
cross-links comprising 2-ureido-4[1H]-pyrimidinone
(UPy) hydrogen-bonding units within the backbone of segmented amphiphilic
macromolecules having hydrophilic poly(ethylene glycol) (PEG). The
bulk materials adopt nanoscopic physical cross-links composed of UPy–UPy
dimers embedded in segregated hydrophobic domains dispersed within
the PEG matrix as comfirmed by cryo-electron microscopy. The amphiphilic
network was swollen with high weight fractions of water (wH2O ≈ 0.8) owing to the high PEG weight
fraction within the pristine polymers (wPEG ≈ 0.9). Two different PEG chain lengths were investigated
and illustrate the corresponding consequences of cross-link density
on mechanical properties. The resulting hydrogels exhibited high strength
and resilience upon deformation, consistent with a microphase separated
network, in which the UPy–UPy interactions were adequately
shielded within hydrophobic nanoscale pockets that maintain the network
despite extensive water content. The cumulative result is a series
of tough hydrogels with tunable mechanical properties and tractable
synthetic preparation and processing. Furthermore, the melting transition
of PEG in the dry polymer was shown to be an effective stimulus for
shape memory behavior.