Tuning the viscoelastic response of hydrogel scaffolds with covalent and dynamic bonds

The processes of growth, proliferation and differentiation of stem cells encapsulated in 3D hydrogel microenvironments are strongly affected by the viscoelastic properties of the platforms. As the viscoelastic response of a hydrogel is determined by the rates of thermally induced dissociation of reversible cross-links, its modulation by introduction of several types of supramolecular and/or dynamic covalent bonds with different characteristic lifetimes has recently become a hot topic. To reduce the number of experiments needed for design of hydrogel microenvironments with required mechanical properties, a model is developed for the viscoelastic and viscoplastic responses of hydrogels with multiple networks bridged by covalent and physical bonds. An advantage of the model is that it (i) involves a small number of material parameters, (ii) describes observations in rheological and mechanical tests in a unified manner, and (iii) predicts conventional measures of viscoelasticity used in the analysis of viability of cells.