Experimental and FE displacement and polymerization stress of bonded restorations as a function of the C-Factor, volume and substrate stiffness

AbstractObjectives ermine the free surface displacement of resin-composite restorations as a function of the C-Factor, volume and substrate stiffness, and to compare the results with interfacial stress values evaluated by finite element analysis (FEA). s e displacement was determined by an extensometer using restorations with 4 or 6 mm diameter and 1 or 2 mm depth, prepared in either bovine teeth or glass. The maximum displacement of the free surface was monitored for 5 min from the start of photoactivation, at an acquisition rate of 1 s−1. Axisymmetric cavity models were performed by FEA. Structural stiffness and maximum stresses were investigated. s ass, displacement showed a stronger correlation with volume (r = 0.771) than with C-Factor (r = 0.395, p < 0.001 for both). For teeth, a stronger correlation was found with C-Factor (r = 0.709; p < 0.001) than with volume (r = 0.546, p < 0.001). For similar dimensions, stress and displacement were defined by stiffness. Simultaneous increases in volume and C-Factor led to increases in stress and surface displacement. Maximum stresses were located at the cavosurface angle, internal angle (glass) and at the dentine–enamel junction (teeth). The displacement of the restorationʹs free surface was related to interfacial stress development. sions ural stiffness seems to affect the shrinkage stress at the tooth/resin-composite interface in bonded restorations. Deep restorations are always problematic because they showed high shear stress, regardless of their width. FEA is the only tool capable of detecting shear stress due to polymerization as there is still no reliable experimental alternative.