Litcius/Paper detail

Building block properties govern granular hydrogel mechanics through contact deformations

Dilara Börte Emiroglu, Aleksandar Bekcic, Dalia Dranseike, Xinyu Zhang, Tomaso Zambelli, Andrew J. deMello, Mark W. Tibbitt

2022Science Advances79 citationsDOIOpen Access PDF

Abstract

Granular hydrogels have been increasingly exploited in biomedical applications, including wound healing and cardiac repair. Despite their utility, design guidelines for engineering their macroscale properties remain limited, as we do not understand how the properties of granular hydrogels emerge from collective interactions of their microgel building blocks. In this work, we related building block features (stiffness and size) to the macroscale properties of granular hydrogels using contact mechanics. We investigated the mechanics of the microgel packings through dynamic oscillatory rheology. In addition, we modeled the system as a collection of two-body interactions and applied the Zwanzig and Mountain formula to calculate the plateau modulus and viscosity of the granular hydrogels. The calculations agreed with the dynamic mechanical measurements and described how microgel properties and contact deformations define the rheology of granular hydrogels. These results support a rational design framework for improved engineering of this fascinating class of materials.

Topics & Concepts

Self-healing hydrogelsRheologyGranular materialMaterials scienceStiffnessContact mechanicsElastic modulusSoft materialsBlock (permutation group theory)Work (physics)Composite materialNanotechnologyMechanicsMechanical engineeringPhysicsMathematicsThermodynamicsEngineeringFinite element methodPolymer chemistryGeometryCellular Mechanics and InteractionsPolysaccharides Composition and ApplicationsHydrogels: synthesis, properties, applications