听觉神经通路在磁声耦合刺激调控运动皮层中的作用

doi:10.3969/j.issn.0258-8021.2021.02.08

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摘要经颅磁声耦合刺激 (TMAS) 技术可以无创地实现包括深部脑区在内的全脑区毫米量级的精准电刺激。现有的实验研究结果已初步证实,TMAS是同时包含耦合电场与声场的复合物理刺激。最新的研究结果表明,听觉神经通路是聚焦超声调节皮层神经活动的必要条件。首次采用听觉通路被破坏的耳聋模型小鼠进行在体 TMAS及TUS的对比刺激,分析听觉神经通路在TMAS神经调控中的作用。在造模后的不同时间点,采集耳聋组小鼠(n=6)与对照组正常小鼠(n=6)在TUS与TMAS作用下诱发的肌电信号 (EMG),并记录运动反馈,对比分析两种刺激对耳聋小鼠与正常小鼠运动皮层的不同调控效果。结果显示,造模后1、12、24、48 h,耳聋小鼠在TMAS与TUS下的运动反馈均逐渐消失,EMG成功率均下降至3.33%;相同时间点的正常小鼠在两种刺激下均能产生运动反馈和EMG,且TUS与TMAS组的EMG成功率无统计学差异(P=0.296),但其TMAS组的EMG均方根幅值大于TUS组,具有统计学差异(P=0.001 1)。结果表明,无论TMAS与TUS,其刺激效果均严重依赖于听觉神经通路的完整性。通过耳聋组与正常组TUS与TMAS刺激结果的对比,验证在对运动皮层刺激时,听觉神经通路的存在是聚焦超声场进行调控的必要条件;而TMAS的刺激效果主要依赖于超声场的调控作用,听觉神经通路对TMAS的调控效果同样具有决定性影响。进而说明,在运动皮层刺激时,TMAS中的耦合电场可提高超声场的调控作用。

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	周晓青
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	殷涛
	刘志朋

关键词 ：经颅磁声耦合刺激, 听觉神经通路, 超声刺激, 耳聋模型鼠, 运动皮层

Abstract：Transcranial magneto-acoustic stimulation (TMAS) technique can noninvasively deliver millimeter-scale precision electrical stimulation of the whole brain, including the deep brain regions. Existing experimental results have preliminarily confirmed that TMAS is a composite physical stimulation containing coupled MA electric field and ultrasonic field simultaneously. Recent research results show that cochlear auditory pathway is a necessary condition for cortical activation by focused ultrasound. In this paper, in vivo TMAS and TUS were contrastively stimulated in deaf model mice with damaged auditory pathway for the first time to analyze the role of auditory pathways in the neuromodulation of TMAS. Electromyography (EMG) signals and motor feedback induced by TUS and TMAS were collected from deaf mice (n=6) and normal mice (as the control group, n=6) at the different time points after the deaf-model building. The different neuromodulation effects of two kinds of stimulations on the motor cortex of deaf mice and normal mice were compared and analyzed. Results showed that: At 1 h, 12 h, 24 h and 48 h after model building, the motor feedback of deaf mice under TMAS and TUS gradually disappeared, and the success rate of EMG decreased to 3.33%; Normal mice at the same time point could produce motor feedback and EMG under the two kinds of stimulations, and there was no statistical difference in the success rate of EMG between the TUS group and the TMAS group (p=0.296); but the root mean square amplitude of EMG in the TMAS group was greater than that in the TUS group, and the difference was statistically significant (p=0.0011). The results indicated that the stimulation effects of both TMAS and TUS were heavily dependent on the integrity of auditory pathways. By comparing the results of TUS stimulation between the deaf group and the normal group, it was verified that the existence of auditory pathway was a necessary condition for ultrasound neuromodulation during motor cortex stimulation; the stimulation effect of TMAS was mainly dependent on the stimulation effect of ultrasonic field, and the auditory pathway also had a decisive influence for neuromodulation with TMAS. It is further suggested that the MA electric field in TMAS promote the influence for neuromodulation by TUS in motor cortex stimulation.

Key words： transcranial magneto-acoustic stimulation cochlear auditory pathways ultrasound stimulation deaf model mice motor cortex

收稿日期: 2021-01-11

PACS:

R318

基金资助:国家自然科学基金(81772003,52077223);国家自然科学基金重大科研仪器研制项目(81927806)

通讯作者: *E-mail: lzpeng67@163.com

作者简介: #中国生物医学工程学会会员

引用本文:

周晓青, 刘睿旭, 谭如欣, 王会琴, 殷涛, 刘志朋. 听觉神经通路在磁声耦合刺激调控运动皮层中的作用[J]. 中国生物医学工程学报, 2021, 40(2): 188-194.
Zhou Xiaoqing, Liu Ruixu, Tan Ruxin, Wang Huiqin, Yin Tao, Liu Zhipeng. The Role of Cochlear Auditory Pathways on Motor CorticalActivation of Transcranial Magneto-Acoustic Stimulation. Chinese Journal of Biomedical Engineering, 2021, 40(2): 188-194.

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2021.02.08 或 http://cjbme.csbme.org/CN/Y2021/V40/I2/188

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