INTRODUCTION: Traumatic brain injury (TBI) is a neurological disorder caused by external biomechanical forces such as sports impacts and vehicular accidents. It is a leading cause of morbidity and long-term disability across all age groups. Beyond acute damage, TBI contributes to chronic neurodegenerative processes and persistent neurological sequelae. Growing clinical and experimental evidence suggests that TBI is also associated with systemic alterations affecting the cardiovascular, respiratory, renal, gastrointestinal, and immune systems. METHODS: This narrative integrative review synthesized recent experimental and clinical studies investigating neurological and systemic complications following TBI. Sources were evaluated for evidence related to neurodegenerative cascades, organ dysfunction, and immune-mediated mechanisms. Findings from animal models and human studies were interpreted contextually to highlight mechanistic insights and clinical relevance. RESULTS: The reviewed literature indicates that TBI is associated with both acute and chronic neurological impairment, while also affecting peripheral organ systems. Reported alterations include cardiovascular instability, pulmonary dysfunction, renal hypoperfusion, gastrointestinal barrier disruption, hepatic cytotoxicity, and immune dysregulation. Several studies suggest that peripheral immune activation may contribute to secondary neuroinflammatory processes and unfavorable neurological outcomes. DISCUSSION: The bidirectional interactions between the injured brain and peripheral organs represent a critical but incompletely understood aspect of TBI pathology. Systemic complications may amplify neuroinflammatory cascades and are increasingly recognized as contributors to progressive neurological decline. Integrating brain-systemic perspectives is essential to better understand the multisystem consequences of TBI. CONCLUSION: TBI is increasingly recognized as a multisystem condition that extends beyond the central nervous system. Improved understanding of brain-systemic interactions may inform the development of therapeutic strategies targeting both neurological injury and associated systemic complications, with the potential to reduce morbidity and mortality following head injury.
Gulia et al. (Thu,) studied this question.