Enzyme-Catalyzed Bottom-Up Synthesis of Mechanically
and Physicochemically Stable Cellulose Hydrogels for Spatial Immobilization
of Functional Colloidal Particles
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Abstract
The
dispersion stabilization of colloidal particles and subsequent
construction of functional materials are of great interest in areas
ranging from colloid chemistry to materials science. A promising strategy
is the spatial immobilization of colloidal particles within gel scaffolds.
However, conventional gels readily deform and even collapse when changes
in environmental conditions occur. Herein, we describe the enzyme-catalyzed
bottom-up synthesis of mechanically and physicochemically stable nanoribbon
network hydrogels composed of crystalline cellulose oligomers in which
cellulose nanocrystals (CNCs) as model colloidal particles are immobilized
spatially. The stiffness of the hydrogels increased with the amount
of CNCs incorporated. Filling the void space of the hydrogels with
hydrophobic polymers resulted in polymer nanocomposites with excellent
mechanical properties. The nanoribbon networks will be useful for
demonstrating the potential functions of colloidal particles