Project Summary More than 50 million people suffer from epilepsy globally. Current anti-epileptic drugs (AEDs) cannot prevent seizures in ~30% of these patients, leading to uncontrolled or refractory epilepsy. Unfortunately, these patients are at extreme risk of Sudden Unexpected Death in Epilepsy (SUDEP), which is the leading cause of death in this cohort. Based on landmark SUDEP studies, the current hypothesis is that recurrent seizures induce extreme cardiorespiratory suppression and/or failure through negative effects on the neural networks that regulate vital functions such as breathing, heart rate and blood pressure. However, it remains unclear how repeated seizures fundamentally affect cardiorespiratory control networks within the brainstem, and by what mechanisms these vital systems fail in SUDEP. Here we aim to characterize the pathophysiologic consequences of repeated seizures in a novel rat model with a known mutation in a potassium channel gene (kcnj16; SSkcnj16-/- rats), in which a specific sound of mild intensity readily and reproducibly causes generalized tonic-clonic seizures (GTCSs). Sound-induced GTCSs in SSkcnj16-/- rats led to a stereotypic pattern of events similar to that described in epilepsy patients, including post-ictal generalized EEG suppression and apnea, followed by respiratory rate (RR) and heart rate (HR) suppression. Repeated seizures (1/day for up to 10 days) led to: 1) augmented post- ictal suppression of RR and HR, reduced ventilatory responses to hypoxic and hypercapnic challenges, and unexpected mortality in ~33% of these rats. Brainstem tissue analyses of SSkcnj16-/- rats exposed to repeated seizures showed evidence of time-dependent increases in inflammation and dysregulation of adenosine (ADO) and serotonin (5-HT) – two powerful modulators of cardiorespiratory neural networks. Finally, pharmacologically augmenting 5-HT with an SSRI (fluoxetine) prevented the progressive suppression of post-ictal RR with repeated seizures. Herein we will test our central hypothesis that repeated seizures cause a progressive brainstem pathology initiated by neuroinflammation and mediated by ADO and 5-HT dysfunction leading to cardiorespiratory suppression and/or failure in SUDEP. The proposed studies utilizing this novel mutant rat model will provide: 1) a comprehensive characterization of the progressive pathophysiological responses to repeated audiogenic seizures, and sequence of events leading to unexpected death (Aim 1), 2) identified mechanisms of dysfunction in inflammatory and/or neuromodulatory pathways within critical cardiorespiratory brainstem nuclei negatively affected by repeated seizures (Aim 2), and 3) interventions that functionally test our hypothesis by blocking neuroinflammation or modulating ADO or 5-HT system activity on the backdrop of repeated seizures (Aim 3). We will utilize a combination of established and cutting-edge technologies to provide unprecedented molecular, cellular and systems-level insig...