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by Keyword: Cell-material interactions
Villacrosa-Ribas, Adria, Duffhues, Danielle C A, van den Bersselaar, Pim, Pragnere, Sarah, Groenen, Bart G W, Azevedo Gonzalez Oliva, Mariana, Ciccone, Giuseppe, Salmeron-Sanchez, Manuel, Bouten, Carlijn V C, Munoz, Jose J, Conte, Vito, (2026). Traction Force Microscopy for Viscoelastic Substrates: A Semi-Analytical Method Advanced Science ,
Traction force microscopy (TFM) quantifies cellular forces at the cell-extracellular matrix interface, yet elastic formulations neglect viscous dissipation and can misinterpret cellular forces on viscoelastic substrates. We introduce a semi-analytical 2D viscoelastic TFM (veTFM) that generalizes the Boussinesq framework of elastic TFM to Generalized Maxwell (GMX) substrates with one or two components. By combining Fourier and Laplace transforms, veTFM quantifies time-resolved tractions in finite-thickness substrates and resolves stress-free reference and substrate pre-stress. We derive criteria for when elastic regimes remain valid in this framework. This positions veTFM as a scalable extension of standard 2D TFM (eTFM) to viscoelastic substrates, identifying when eTFM remains sufficient, which elastic limit applies, and when full viscoelastic quantification is required. Applied to beating cardiomyocytes, epithelial cells, and dermal fibroblasts cultured on linear-polyacrylamide and alginate viscoelastic hydrogels, veTFM shows that the elastic or viscoelastic regime engaged by the cell depends on timescale matching between the loading rate and the substrate's relaxation times. Notably, for the Generalized Maxwell substrates analyzed here, viscoelastic traction magnitudes scale with the substrate's total dissipation rather than individual relaxation times, with total dissipation setting traction magnitude and timescale matching determining whether the cell engages the substrate in an elastic or viscoelastic regime.
JTD Keywords: Biomaterials, Cell, Cell-material interactions, Extracellular-matrix viscoelasticity, Focal adhesions, Guide, Hydrogels, Numerical inversion, Semi-analytical methods, Stress relaxation, Viscoelastic hydrogels, Viscoelastic traction force microscopy
Gugutkov, Dencho, Gonzalez-Garcia, Cristina, Altankov, George, Salmeron-Sanchez, Manuel, (2011). Fibrinogen organization at the cell-material interface directs endothelial cell behavior
Journal of Bioactive and Compatible Polymers , 26, (4), 375-387
Fibrinogen (FG) adsorption on surfaces with controlled fraction of -OH groups was investigated with AFM and correlated to the initial interaction of primary endothelial cells (HUVEC). The -OH content was tailored making use of a family of copolymers consisting of ethyl acrylate (EA) and hydroxyl ethyl acrylate (HEA) in different ratios. The supramolecular distribution of FG changed from an organized network-like structure on the most hydrophobic surface (-OH(0)) to dispersed molecular aggregate one as the fraction of -OH groups increases, indicating a different conformation by the adsorbed protein. The best cellular interaction was observed on the most hydrophobic (-OH(0)) surface where FG assembled in a fibrin-like appearance in the absence of any thrombin. Likewise, focal adhesion formation and actin cytoskeleton development was poorer as the fraction of hydroxy groups on the surface was increased. The biological activity of the surface-induced FG network to provide 3D cues in a potential tissue engineered scaffold, making use of electrospun PEA fibers (-OH(0)), seeded with human umbilical vein endothelial cells was investigated. The FG assembled on the polymer fibers gave rise to a biologically active network able to direct cell orientation along the fibers (random or aligned), promote cytoskeleton organization and focal adhesion formation.
JTD Keywords: Fibrinogen, Cell-material interactions, HUVEC, Electrospun fibers, Fibrinogen organization, Cell-material interface, Endothelial cell behavior, Ethyl acrylate, Hydroxyl ethyl acrylate