posted on 2020-12-17, 19:40authored byMalika Talantikite, Taylor C. Stimpson, Antoine Gourlay, Sophie Le-Gall, Céline Moreau, Emily D. Cranston, Jose M. Moran-Mirabal, Bernard Cathala
Thermoresponsive hydrogels present
unique properties, such as tunable
mechanical performance or changes in volume, which make them attractive
for applications including wound healing dressings, drug delivery
vehicles, and implants, among others. This work reports the implementation
of bioinspired thermoresponsive hydrogels composed of xyloglucan (XG)
and cellulose nanocrystals (CNCs). Starting from tamarind seed XG
(XGt), thermoresponsive XG was obtained by enzymatic degalactosylation
(DG-XG), which reduced the galactose residue content by ∼50%
and imparted a reversible thermal transition. XG with native composition
and comparable molar mass to DG-XG was produced by an ultrasonication
treatment (XGu) for a direct comparison of behavior. The hydrogels
were prepared by simple mixing of DG-XG or XGu with CNCs in water.
Phase diagrams were established to identify the ratios of DG-XG or
XGu to CNCs that yielded a viscous liquid, a phase-separated mixture,
a simple gel, or a thermoresponsive gel. Gelation occurred at a DG-XG
or XGu to CNC ratio higher than that needed for the full surface coverage
of CNCs and required relatively high overall concentrations of both
components (tested concentrations up to 20 g/L XG and 30 g/L CNCs).
This is likely a result of the increase in effective hydrodynamic
volume of CNCs due to the formation of XG-CNC complexes. Investigation
of the adsorption behavior indicated that DG-XG formed a more rigid
layer on CNCs compared to XGu. Rheological properties of the hydrogels
were characterized, and a reversible thermal transition was found
for DG-XG/CNC gels at 35 °C. This thermoresponsive behavior provides
opportunities to apply this system widely, especially in the biomedical
field, where the mechanical properties could be further tuned by adjusting
the CNC content.