Granular hydrogels have evolved into an innovative technology for biomedicine. Unlike conventional hydrogels, granular hydrogels display dynamic properties like injectability and porosity, making them feasible for applications in 3D bioprinting and tissue engineering. High-energy electron irradiation combines sterilization and tuning of hydrogel properties without adding potentially cytotoxic chemicals. In this study, granular agarose/alginate hydrogels are prepared by electrospraying. Utilizing 10 MeV electron irradiation, the granular hydrogels are treated in a dose range of 0 kGy-30 kGy relevant for sterilization. Herein, a size reduction of the microparticles is observed. Mechanical properties of individual agarose/alginate beads are examined using AFM measurements revealing a gel softening attributed to radiation induced chain scission. Shear-thinning and self-healing characteristics of the entire granular hydrogel are studied employing rheology. Although viscoelasticity changes under irradiation, shear-thinning and self-healing prevails. These dynamic properties enable injection, which is demonstrated for 27 G needles. This study presents a mechanical characterization of high-energy electron irradiated granular agarose/alginate hydrogels that extends the diversity of available injectable hydrogels and provides a basis for biomedical applications of this scaffold.
Keywords: High-energy electron irradiation; Injectable hydrogel beads; Shear-thinning and self-healing granular hydrogel.
Copyright © 2022 Elsevier Ltd. All rights reserved.