迷走神经电刺激
迷走神经
医学
导水管周围灰质
伤害
刺激
光遗传学
神经科学
谷氨酸的
眼心反射
神经病理性疼痛
麻醉
神经调节
脑深部刺激
运动前神经元活动
中枢神经系统
外围设备
神经元
核心
中脑
孤核
作者
Xiaoqi Peng,Yehao Liu,Yi Liu,Yunfeng Mao,Qianhui Xia,An Liu,Qian Dai,Yingju Tai,Bin Luo,Hao Wang,Yuanyin Wang,Fang Kang,Haitao Wang,Zhi Zhang
标识
DOI:10.1038/s41467-026-72214-0
摘要
Despite its long-recognized effects in relieving pain, the neural substrates of auricular stimulation remain elusive. Here, we show that trans-auricular vagus nerve stimulation (taVNS), i.e., electrical stimulation of the auricular concha, effectively induces analgesia in a mouse model of neuropathic pain. Viral tracing, microendoscopic calcium imaging, and multi-electrode recordings reveal that auricular vagal signals travel to the jugular-nodose ganglia (JNG), which in turn connect to pro-opiomelanocortinergic neurons in nucleus tractus solitarius (NTS), subsequently activating glutamatergic neurons in ventrolateral periaqueductal gray (vlPAG). Optogenetic stimulation of central vagus terminals, JNG-derived auricular peripheral fibers, or vlPAG-projecting NTS neurons mimics taVNS-induced analgesia, whereas chemogenetic silencing of central vagus terminals or NTS neurons abolishes this effect. This study identifies an auricle–to–brain circuit underlying taVNS-driven analgesia in mice, with potential for facilitating taVNS optimization for pain management and other neurological conditions. The neuroanatomical basis of auricular vagus nerve stimulation-induced analgesia remains unclear. Here, the authors identify an auricle-to-brain axis from the auricular concha to the ventrolateral periaqueductal gray, which engages the descending antinociceptive pathway.
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