Traumatic brain injuries (TBIs) are a major cause of disability among war veterans, leading to behavioral dysfunction and post-concussive symptoms such as depression, anxiety, pain, and substance abuse. These symptoms are thought to be caused by neural inflammation combined with a malfunctioning autonomic nervous system following injury, called dysautonomia. Dysautonomia leads to changes in heart and respiratory rate, increased fatigue, and has been shown to be able to predict future behavioral outcomes such as depression. Vagal nerve stimulation (VNS) is currently being examined as a treatment for blast trauma, as the vagus nerve helps regulate the autonomic nervous system. I predict that VNS following blast exposures will reduce the neural inflammation and severity of dysautonomia following blast TBIs, in turn lessening the chronic behavioral dysfunction that normally occurs after blasts. To examine the effects of VNS on TBIs, I looked at both vital signs and behavioral dysfunction immediately and chronically following the blast. A shock tube that generates clinically relevant overpressure waves was utilized to simulate chronic (3x blast exposures (or sham exposure)) in 11-week-old C57BL/6J mice (n=5-6 per group, from two cohorts of mice). In addition to analyzing cytokine expression to determine inflammation and vital signs, several behavioral assays were run, including: operant conditioning, t-maze, y-maze, acoustic startle, and photophobia, to examine both biological and behavioral changes following blast and VNS treatment. Thus far it appears likely that the VNS treatment has lessened the severity of multiple measures of dysfunction, including pain, startle sensitization, and inflammation. This demonstrates that VNS could be a potential therapeutic for blast TBIs but further research, including running more mice to obtain a larger sample size, is necessary to draw more conclusions.