Litcius/Paper detail

Chemical and Microstructural Characterization of pH and [Ca2+] Dependent Sol-Gel Transitions in Mucin Biopolymer

Austin Curnutt, Kaylee Smith, Emily Darrow, Keisha B. Walters

2020Scientific Reports69 citationsDOIOpen Access PDF

Abstract

Abstract Mucus is responsible for controlling transport and barrier function in biological systems, and its properties can be significantly affected by compositional and environmental changes. In this study, the impacts of pH and CaCl 2 were examined on the solution-to-gel transition of mucin, the primary structural component of mucus. Microscale structural changes were correlated with macroscale viscoelastic behavior as a function of pH and calcium addition using rheology, dynamic light scattering, zeta potential, surface tension, and FTIR spectroscopic characterization. Mucin solutions transitioned from solution to gel behavior between pH 4–5 and correspondingly displayed a more than ten-fold increase in viscoelastic moduli. Addition of CaCl 2 increased the sol-gel transition pH value to ca. 6, with a twofold increase in loss moduli at low frequencies and ten-fold increase in storage modulus. Changing the ionic conditions—specifically [H + ] and [Ca 2+ ] —modulated the sol-gel transition pH, isoelectric point, and viscoelastic properties due to reversible conformational changes with mucin forming a network structure via non-covalent cross-links between mucin chains.

Topics & Concepts

ViscoelasticityIsoelectric pointBiopolymerMucinIonic strengthDynamic mechanical analysisRheologyZeta potentialSelf-healing hydrogelsChemical engineeringDynamic modulusChemistryElastic modulusDynamic light scatteringMaterials scienceDivalentPolymerBiophysicsPolymer chemistryBiochemistryAqueous solutionOrganic chemistryNanotechnologyComposite materialEnzymeEngineeringBiologyNanoparticlePolysaccharides Composition and ApplicationsSurfactants and Colloidal SystemsPolysaccharides and Plant Cell Walls