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Thermoresponsive Injectable Hydrogel To Mimic the Heat- and Strain-Stiffening Behavior of Biopolymers toward Muscle Cell Proliferation

Debasish Nath, Jahanvi Ralhan, Jojo P. Joseph, Chirag Miglani, Asish Pal

2024Biomacromolecules29 citationsDOI

Abstract

Injectable hydrogels with nonlinear mechanical attributes to emulate natural biopolymers hold paramount significance in tissue engineering, offering the potential to create scaffolds that seamlessly mimic the biomechanical intricacies of living tissues. Herein, we unveil a synthetic design strategy employing Schiff base chemistry to furnish a peptide–polymer hierarchical contractile injectable hydrogel network. This innovative design demonstrates cross-linking of supramolecular peptide nanostructures such as nanofibers, 1 NF, and twisted bundles, 1 TB, with a thermosensitive aldehyde-functionalized polymer, P CHO . These networks exhibit interesting nonlinear mechanical stiffening responses to temperature and external stress. Furthermore, the hydrogels transform into a gel state at physiological temperature to exhibit injectable behavior and demonstrate compression load-bearing capabilities. Finally, the hydrogel network exhibits excellent biocompatibility and cell proliferation toward fibroblast, L929, and myoblast, C2C12, to validate their use as potential extracellular matrix mimetic injectable scaffolds.

Topics & Concepts

Self-healing hydrogelsTissue engineeringC2C12BiocompatibilityNanofiberExtracellular matrixNanotechnologyMaterials scienceFibroblastSILKBiophysicsChemistryBiomedical engineeringPolymer chemistryBiochemistryMyogenesisComposite materialBiologyMedicineIn vitroMetallurgySupramolecular Self-Assembly in MaterialsConnective tissue disorders researchAdvanced Materials and Mechanics
Thermoresponsive Injectable Hydrogel To Mimic the Heat- and Strain-Stiffening Behavior of Biopolymers toward Muscle Cell Proliferation | Litcius