Background/purpose: Fibroblasts are actively and dynamically involved in wound healing (dermal regeneration, wound contraction, and scar contracture) and fibrosis. Fibroblast-seeded collagen gels provide an in vitro model for these processes. Over time, fibroblasts will contract the gels, but the mechanisms are not completely understood. This research investigated the influence of cell density and collagen crosslinking on the contraction of fibroblast-populated gels by varying seeding density and blocking the catalyzing enzyme lysyl oxidase, respectively.
Methods: Collagen gels were seeded with fibroblasts at either 3 x 104 or 1 x 105 cells/mL and incubated with or without the lathyrogen beta-aminoproprionitrile (BAPN) for 8 days. In all, four experimental groups were analyzed: low cell density control, high cell density control, low density plus BAPN, and high density plus BAPN. Digital images were taken daily and gel area was calculated.
Results: Contraction was dependent on cell concentration, with higher density gels being contracted to a greater extent. BAPN had no effect until after day 2 when it inhibited (high density) or almost completely blocked (low density) the gel contraction. BAPN also reduced total long-term contraction.
Conclusion: The results demonstrated a bimodal nature to fibroblast-mediated gel contraction: a cell density-dependent component, most likely mediated through cellular forces, and a delayed collagen crosslinking component that could be blocked by BAPN. In the long-term, similar contraction rates among the four experimental groups, particularly between the two BAPN groups, implies that the collagen crosslinking effect is discrete and independent of cell density.