Pain associated with surgery is experienced by millions of patients every year. Post-surgical pain usually resolves as the surgical site heals. However, up to half of the patients develop chronic pain after surgery. Crucially, little is known about the mechanisms that aid in the resolution of postoperative pain. Moreover, opioids remain the mainstay treatment for post- surgical pain which are fraught with serious side-effects and crucially - abuse liabilities. The goal of our research is to validate an endogenous mechanism that leads to the resolution of post- surgical pain. Metabolism is inextricably linked to every aspect of cellular function. However, the specific effects surgery has on the metabolism of sensory neurons and how these changes influence the resolution of post-surgical pain are not known. Hence, we determined that surgical trauma suppresses pyruvate oxidation while increase glutamine catabolism was associated with the resolution of post-surgical pain. The selective increase of glutamine oxidation was in part mediated by the glutamine transporter ASCT2 which replenished the Krebs cycle metabolic intermediates that have been depleted due to reduced pyruvate oxidation. This process is known as anaplerosis. Moreover, disruption of ASCT2 expression prevented the resolution of postoperative pain. Hence, we aim to validate that ASCT2 is critical for the resolution of post- surgical pain and can be manipulated for the resolution of postoperative pain. Using molecular, biochemical, metabolic assays and innovative multiband fluorescence imaging method of intact DRGs, we aim to achieve our objective. Moreover, we propose to validate an innovative RNA- based strategy that enhances ASCT2 expression. Validation of endogenous targets that resolve postoperative pain can have broad impact in advancing our knowledge of the transition of acute pain to chronic and lead to urgently needed public health advancements.