Objective To investigate the activation of inflammasome and microglial cells and the formation of abnormal neonatal neurons in a rat model of lithium-pilocarpine-induced epilepsy， as well as the mechanism of action of inflammasome in the development and progression of epilepsy by activating microglial cells and promoting the formation of abnormal neonatal neurons.Methods Rats were given intraperitoneal injection of lithium and pilocarpine to establish a model of epilepsy. Rats were divided into Sham group （saline control group， n=12）， Pilo group （lithium-pilocarpine epileptogenic group， n=20） and Pilo+MCC950 group （lithium-pilocarpine epileptogenic followed by administration of NLRP3 inhibitor group， n=20）. The behavioral manifestations of epilepsy were observed in the acute stage； pathological sections were used to observe brain tissue injury and cell activation； molecular assays were used to measure the expression of inflammasome and other molecules； in vitro cell model rescue experiments were used to verify the effect of inflammasome.Results In the Pilo group， there were six rats with grade V seizures， five with grade IV seizures， and two with grade III seizures， while in the Pilo+MCC950 group， there were no rats with grade V seizures， and there were six rats with grade IV seizures， eight with grade III seizures， and two with grade II seizures. Compared with the Pilo+MCC950 group， the Pilo group had a significantly shorter latency period of myotonic seizures and significantly higher number and longer duration of grade ≥III seizure. The Pilo group had significantly higher levels of NLRP3， pro-caspase-1， four inflammatory cytokines， BNDF， and ERK than the Pilo+MCC950 group. Immunofluorescence assay showed the activation of a large number of microglial cells and the presence of a large number of abnormal neonatal neurons in the Pilo group. After in vitro cell experiments， the results of ELISA validated the role of inflammasome.Conclusion In the rat model of lithium-pilocarpine-induced epilepsy， inflammasome NLRP3 is activated by external inflammatory stimuli and then produces a large number of inflammatory cytokines， thereby activating microglial cells to secrete BDNF and activate the ERK signaling pathway， and thus it regulates the formation and aggregation of abnormal neonatal neurons and participates in the development and progression of epilepsy. ［Journal of International Neurology and Neurosurgery, 2024, 51(4): 28-35］