Abstract
Traumatic brain injury (TBI) is a significant cause of death and disability, affecting nearly 300,000 Americans annually. Beyond the immediate physical damage, TBI induces chronic neuroinflammation and long-term neurodegeneration, leading to various neurologic and psychiatric disorders. This review examines the cerebrovascular unit (CVU), particularly the cerebral endothelial cells and their critical role in the aftermath of TBI. Following TBI, the CVU undergoes functional changes to counteract inflammation, repair endothelial damage, and promote angiogenesis. However, dysregulation of these protective mechanisms can lead to chronic neuroinflammation, increased cerebrovascular permeability, and systemic endothelial dysfunction. The review explores the molecular and cellular responses of the CVU following TBI, highlighting the roles of inflammatory cytokines, oxidative stress, and various endothelial transport mechanisms. Moreover, TBI-related endothelial dysfunction may extend beyond the brain, potentially contributing to systemic complications such as acute respiratory distress syndrome and multisystem organ failure. Despite the gravity of these conditions, clinical breakthroughs remain limited. This review underscores the necessity for targeted therapeutic strategies to mitigate endothelial dysfunction and improve long-term outcomes for TBI patients. Future research is essential to elucidate the precise mechanisms driving CVU dysfunction and to develop interventions that can alleviate the chronic effects of TBI.