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. 2019 Oct;86(4):626-640.
doi: 10.1002/ana.25554. Epub 2019 Aug 12.

Subicular pyramidal neurons gate drug resistance in temporal lobe epilepsy

Cenglin Xu  1 Yi Wang  1 Shuo Zhang  1 Jiazhen Nao  1 Yao Liu  1 Ying Wang  1 Fang Ding  2 Kai Zhong  3 Liying Chen  1 Xiaoying Ying  1 Shuang Wang  2 Yudong Zhou  1 Shumin Duan  1 Zhong Chen  1   2
Affiliations

Subicular pyramidal neurons gate drug resistance in temporal lobe epilepsy

Cenglin Xu et al. Ann Neurol. 2019 Oct.

Abstract

Objective: Drug-resistant epilepsy causes great clinical danger and still lacks effective treatments.

Methods: Here, we used multifaceted approaches combining electrophysiology, optogenetics, and chemogenetics in a classic phenytoin-resistant epilepsy model to reveal the key target of subicular pyramidal neurons in phenytoin resistance.

Results: In vivo neural recording showed that the firing rate of pyramidal neurons in the subiculum, but not other hippocampal subregions, could not be inhibited by phenytoin in phenytoin-resistant rats. Selective inhibition of subicular pyramidal neurons by optogenetics or chemogenetics reversed phenytoin resistance, whereas selective activation of subicular pyramidal neurons induced phenytoin resistance. Moreover, long-term low-frequency stimulation at the subiculum, which is clinically feasible, significantly inhibited the subicular pyramidal neurons and reversed phenytoin resistance. Furthermore, in vitro electrophysiology revealed that off-target use of phenytoin on sodium channels of subicular pyramidal neurons was involved in the phenytoin resistance, and clinical neuroimaging data suggested the volume of the subiculum in drug-resistant patients was related to the usage of sodium channel inhibitors.

Interpretation: These results highlight that the subicular pyramidal neurons may be a key switch control of drug-resistant epilepsy and represent a new potential target for precise treatments. ANN NEUROL 2019;86:626-640.

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