Characterizing the viscoelastic properties of different fibroblasts in 2D and 3D collagen gels

Abstract

AbstractWe assessed cell mechanical properties in both 2D and 3D environments employing compliant type I collagen matrices. Firstly, collagen gels of varying stiffness were prepared using a photocrosslinker to increase gel stiffness. Using methacrylic anhydride and UV light, a 10-fold increase in apparent Young’s modulus with respect to the soft collagen gel was achieved (0.2 kPa to 2 kPa). In addition, cells were plated onto the different collagen gels and hard Petri dishes (as a super stiff substrate) and their mechanical properties were evaluated. An increase in apparent Young’s modulus was observed in Dupuytren fibroblasts behavior when increasing substrate stiffness, supporting its myofibroblast phenotype (3.8 kPa to 5.2 kPa from soft collagen gels to hard Petri dishes). Secondly, gel’s mechanics, in which fibroblasts were embedded, were evaluated over time to assess cells contraction properties. Gel’s apparent Young’s modulus increased over time regardless of fibroblasts type and cells presented dendritic protrusions. Rheological properties of both cells and gels were extracted using AFM sweep frequency scheme and power law structural damping model for data analysis. As a summary, we have found that fibroblasts contractile properties, related to myofibroblast differentiation and development are highly influenced on the mechanical properties of the surrounding environment, being stiffer environments those that favor the increase in fibroblast mechanical tension.