Although spinal cord injury (SCI) is a debilitating condition that presents a large socioeconomic problem in the United States, there is currently no treatment that reliably reduces morbidity and mortality. Current research is aimed at identifying mechanisms involved in the pathophysiology of SCI and using this knowledge to develop rational treatments. We have observed plasma membrane compromise in the acute (within 10 minutes), sub-acute (3 days), and chronic phases (5 weeks) in a rat model of contusion SCI and postulate that it negatively affects neurological outcome. Holes/tears in the plasma membrane were assessed with a dye exclusion assay, in which a fluorescent cellimpermeant dye was injected into the cerebrospinal fluid prior to sacrifice; therefore, cellular uptake of the dye is indicative of plasma membrane compromise. As early as 10 minutes after SCI, widespread uptake of permeability markers was evident in neuronal cell bodies as well as axonal projections. The number of permeable cells and the size of the membrane breaches (measured by using permeability markers of various sizes) varied with distance from the injury site, with larger disruptions located closer to the epicenter. Greater cellular uptake was observed when the impact force was increased (200 > 150 > 100 kdyn > sham). At longer time points (3 days and 5 weeks), substantial permeability marker uptake was observed in axons but not in cell bodies. Cells with increased permeability displayed a variety of pathomorphological alterations, including swelling, blebbing, retraction bulb formation, neurofilament loss, and fragmentation, suggesting that increased plasma membrane permeability is detrimental to cell survival and function. We therefore investigated a clinically-relevant treatment strategy designed to restore plasma membrane integrity. Animals were treated with citicoline, a molecule utilized in the endogenous synthesis of phosphatidylcholine (the major membrane component in mammalian cells). Citicoline has been shown to be beneficial in numerous studies of neurological disease, improving overall outcome by increasing phospholipid synthesis and attenuating phospholipid destruction (by reducing phospholipase A2 activity). However, these mechanisms have not been explored in a model of SCI. When compared to injured animals receiving vehicle (saline) injections, citicoline treatment after SCI did not have a statistically significant effect on cytoplasmic PLA2 activity (at 24h postinjury), the density of permeable axons (at 3 days post-injury), or the lesion volume (at 3 days post-injury). Since citicoline may improve neurological outcome after SCI through mechanisms we did not directly assess, we then conducted a longer-term study to evaluate the overall efficacy of citicoline treatment in terms of longer-term functional and histological consequences. Citicoline did not have a biologically significant effect on behavioral recovery (evaluated during open field locomotion, grid walk and hyperalgesia testing weekly for up to 5 weeks post-injury) or lesion volume (at 5 weeks post-injury). The lack of citicoline-mediated effect may be attributed to experimental parameters (e.g., dosing or sensitivity of outcome measures) or biological inefficacy. Although we were not able to demonstrate that citicoline improves outcome after SCI, the finding that plasma membrane damage occurs in a persistent fashion and is associated with pathophysiological cellular alterations may provide fundamental knowledge necessary for developing treatments targeted at membrane repair. Future work examining the complex mechanisms causing prolonged membrane damage after SCI and evaluating strategies for manipulating these pathways (potentially using citicoline in combination with other pharmacological agents) may lead to a clinically effective therapy.