Advances in Cellulose-Based Hydrogels

© 2022 by the authors; CC BY-NC-ND license

nanocellulose hydrogels; cellulose-based nanosponges; heterogeneous catalysis; acetalization; metal-catalyzed reactions; sustainability; carboxymethylcellulose; alginate; polyacrylamide; silver flake composite; conductive hydrogel; soft hydrogel; stretchable hydrogel; electromyogram; conductive hydrogel; cellulose; tissue engineering; hydrogel design and characterization; electro-active tissues; cellulose pulp; polyurethane; curcumin; antioxidant properties; non-cytotoxicity; barrier properties; mechanical properties; cellulose; cellulose derivatives; hydrogels; photocatalytic composites; in situ growth; macroporous structure; synergistic antibacterial; rapid hemostatic; carboxymethyl cellulose; wound dressing; hydrogel; ZIF-L; polyvinyl alcohol; phase separation technique; methylcellulose; citric acid; crosslinking; pH-responsive; silver nanoparticles (AgNPs); carboxymethyl cellulose; superabsorbent gels; enzymatic biodegradability; spherical control; molding processability; date palm-derived cellulose nanocrystal; guar gum hydrogel; sesame oil; candelilla wax; oleogel; drug delivery; carboxymethylcellulose; tannic acid; conductive hydrogel; injectable hydrogel; adhesive hydrogel; 3D printing; direct printing; HPMC; coaxial electrospinning; core–shell nanohybrids; orodispersible drug delivery; fast dissolution; poorly water-soluble drug; cellulose; hydrogels; biomedical engineering; application; Carbotrace 480; microalgae; defibrillated celluloses; hydrogels; antimicrobial activity; 2-(dimethylamino)ethyl methacrylate; gamma irradiation; hydrogel; hydrogel electrolytes; deep eutectic solvents; hydroxypropyl cellulose; rheology; antimicrobial gels; biocompatibility; n/a