Internal fluid flow increases cellular interconnects between Medial Collateral Ligament fibroblasts and cellular extensions within three-dimensional collagen matrixes

The interconnectivity of fibroblasts within the ligamentous extracellular matrix has been largely overlooked. Studies on the cell-to-cell contacts with their neighbors via gap junctions in ligament fibroblasts, and works on the ability of fibroblasts to generate interconnected networks in vivo, suggest interfibroblastic interactions play an important role in fundamental biological processes, including homeostasis and wound healing. The current study examines how fluidic shear stresses imposed by internal flow can be used to mediate the formation of three-dimensional, interconnected fibroblast networks within collagen solutions. Several fibroblast-collagen solutions were exposed to shear stresses via Poiselle Flow. The consequent changes in cell networking, interconnections, and cell morphology within collagen matrixes exhibited by cells derived from Bovine Medial Collateral Ligaments were analyzed. Results illustrate that higher imposed stresses generate cells with more dendritic and/or branched morphologies, which form more visible three-dimensional networks within collagen matrixes than fibroblast-collagen solutions that were unexposed to shear stress.