Prelabor rupture of the fetal membranes affects approximately 10% of women at term, resulting in an increased risk of maternal and neonatal infection. Evidence suggests that membrane rupture is related to biochemical processes involving the extracellular matrix of the membranes. We tested the hypothesis that prelabor ruptured membranes are characterized by reduced collagen concentrations, altered collagen cross-link profiles, and increased concentrations of biomarkers of oxidative damage. We also set out to determine whether these effects are modulated by ascorbic acid status. In a case-control study, we explored the role that ascorbic acid, oxidative stress, collagen, and collagen cross-links play in determining membrane integrity and developed a functional assay to assess membrane proteolytic susceptibility. Prelabor ruptured membrane had a reduced ascorbic acid concentration in comparison with controls while protein carbonyl and malondialdehyde concentrations were increased. Collagen concentrations were also reduced in prelabor ruptured membrane, and while the concentration of collagen cross-links was not significantly different between prelabor and timely ruptured membrane, there was a regional variation in cross-link ratio within the amniotic sac. Proteolytic resistance in vitro was reduced in prelabor ruptured membrane and also exhibited regional variation within the amniotic sac. Our findings are strongly supportive of a role for the enhanced degradation of membrane collagen in the determination of prelabor rupture of fetal membranes. The formation of the rupture initiation site is a function of a regional variation in collagen cross-link ratio. Tissue ascorbic acid status may be an important mediator of these processes.