Background: Lidocaine is extensively utilized as an anesthetic in clinical settings; however, it has demonstrated significant neurotoxicity when administered for spinal anesthesia. The specific mechanisms underlying lidocaine-induced neurotoxicity are poorly understood. Objective: This study aimed to investigate the mechanisms through which lidocaine induces neurotoxicity, focusing on its effects on intracellular calcium release and the activation of CaMKⅡ and MAPKs pathways, as well as to evaluate the potential protective effects of cilnidipine. Methods: The investigation has employed both in vitro cell models and in vivo mouse models to conduct the experiments. Neuronal cell viability has been assessed following lidocaine treatment, and neurological function has been evaluated in mice after intrathecal injection of lidocaine. Intracellular calcium levels, CaMKⅡ activation, and the phosphorylation of p38 and p65 have been measured in cultured hippocampal neuronal cells and mouse brain tissues. The effects of the calcium channel blocker cilnidipine on these parameters have also been examined. Results: Lidocaine treatment led to a reduction in cell viability in cultured neuronal cells and induced neurological dysfunction in mice. It increased intracellular Ca2+ levels and activated CaMKⅡ in both cultured neuronal cells and mouse brain tissues. Lidocaine also elevated the phosphorylation levels of p38 and p65 in neuronal cells. These effects have been suppressed by cilnidipine, indicating a calcium-dependent mechanism. Conclusion: This study suggests that lidocaine induces neurotoxicity through a calcium-dependent activation of CaMKⅡ and MAPK pathways, leading to neuronal apoptosis and dysfunction. Cilnidipine has been found to exhibit promise as a protective agent against lidocaine-induced neurotoxicity.
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