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Acetic Acid Enables Precise Tailoring of the Mechanical Behavior of Protein-Based Hydrogels

Marina Slawinski, Maria Kaeek, Yair Rajmiel, Luai R. Khoury

2022Nano Letters20 citationsDOIOpen Access PDF

Abstract

Engineering viscoelastic and biocompatible materials with tailored mechanical and microstructure properties capable of mimicking the biological stiffness (<17 kPa) or serving as bioimplants will bring protein-based hydrogels to the forefront in the biomaterials field. Here, we introduce a method that uses different concentrations of acetic acid (AA) to control the covalent tyrosine-tyrosine cross-linking interactions at the nanoscale level during protein-based hydrogel synthesis and manipulates their mechanical and microstructure properties without affecting protein concentration and (un)folding nanomechanics. We demonstrated this approach by adding AA as a precursor to the preparation buffer of a photoactivated protein-based hydrogel mixture. This strategy allowed us to synthesize hydrogels made from bovine serum albumin (BSA) and eight repeats protein L structure, with a fine-tailored wide range of stiffness (2-35 kPa). Together with protein engineering technologies, this method will open new routes in developing and investigating tunable protein-based hydrogels and extend their application toward new horizons.

Topics & Concepts

Self-healing hydrogelsBovine serum albuminMicrostructureMaterials scienceProtein engineeringNanotechnologyTyrosineBiocompatible materialChemical engineeringChemistryBiomedical engineeringPolymer chemistryComposite materialChromatographyBiochemistryEnzymeMedicineEngineeringCellular Mechanics and InteractionsHydrogels: synthesis, properties, applications3D Printing in Biomedical Research
Acetic Acid Enables Precise Tailoring of the Mechanical Behavior of Protein-Based Hydrogels | Litcius