Abstract
Synthetic hydrogels formed from poly(ethylene glycol) (PEG) are widely used to study how cells interact with their extracellular matrix. These in vivo-like 3D environments provide a basis for tissue engineering and cell therapies but also for research into fundamental biological questions and disease modeling. The physical properties of PEG hydrogels can be modulated to provide mechanical cues to encapsulated cells; however, the impact of changing hydrogel stiffness on the diffusivity of solutes to and from encapsulated cells has received only limited attention. This is particularly true in selectively cross-linked “tetra-PEG” hydrogels, whose design limits network inhomogeneities. Here, we used a combination of theoretical calculations, predictive modeling, and experimental measurements of hydrogel swelling, rheological behavior, and diffusion kinetics to characterize tetra-PEG hydrogels’ permissiveness to the diffusion of molecules of biologically relevant size as we changed polymer concentration, and thus hydrogel mechanical strength. Our models predict that hydrogel mesh size has little effect on the diffusivity of model molecules and instead predicts that diffusion rates are more highly dependent on solute size. Indeed, our model predicts that changes in hydrogel mesh size only begin to have a non-negligible impact on the concentration of a solute that diffuses out of hydrogels for the smallest mesh sizes and largest diffusing solutes. Experimental measurements characterizing the diffusion of fluorescein isothiocyanate (FITC)-labeled dextran molecules of known size aligned well with modeling predictions and suggest that doubling the polymer concentration from 2.5% (w/v) to 5% produces stiffer gels with faster gelling kinetics without affecting the diffusivity of solutes of biologically relevant size but that 10% hydrogels can slow their diffusion. Our findings provide confidence that the stiffness of tetra-PEG hydrogels can be modulated over a physiological range without significantly impacting the transport rates of solutes to and from encapsulated cells.
Highlights
Cells’ interactions with their local environment are known to play central roles in regulating processes including proliferation, migration, differentiation, and phenotypic maintenance.[1−3] By extension, these interactions are involved in dysregulation of cell behavior in pathologies
Our findings show that hydrogel stiffness can be modulated over a large range while only impacting diffusivity negligibly, as we only observed significant changes in diffusion at high polymer concentrations that are less suitable for encapsulating cells
We show that altering polymer concentration in our tetra-poly(ethylene glycol) (PEG) design allows us to produce hydrogels with different mechanical stiffnesses without significantly impacting diffusivity for hydrogels up to a polymer concentration of 5%
Summary
Cells’ interactions with their local environment are known to play central roles in regulating processes including proliferation, migration, differentiation, and phenotypic maintenance.[1−3] By extension, these interactions are involved in dysregulation of cell behavior in pathologies. Understanding the impact of mechanical and biological cues cells receive from their surroundings is key in both disease modeling and the development of regenerative therapies.[4,5] While the ability of whole organisms and tissue explants to provide physiologically relevant environments to cells are unrivalled, there is a need for simpler reductionist models that allow for studies into how specific cues impact cellular behaviors Such models have the potential to identify underlying mechanisms that govern complex tissue pathologies, can reveal fundamental insights into cell-matrix interactions, and may inform methods to engineer tissues for regenerative applications.
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