阈下强度的超高频重复经颅磁刺激可通过时间总和诱导阈上运动反应。

Hieu Nguyen, Charlotte Qiong Li, Samantha Hoffman, Zhi-De Deng, Yihong Yang, Hanbing Lu
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摘要

目的:经颅磁刺激(TMS经颅磁刺激(TMS)线圈产生的电场在进入大脑后会迅速减弱。这给实现对大脑深层结构的聚焦刺激带来了挑战。神经元元件,包括轴突、树突和细胞体,都表现出特定的时间常数。当暴露于高频率的重复经颅磁刺激脉冲时,神经元膜电位会产生累积效应,导致时间累加。本研究旨在确定高频率、亚阈值强度的 TMS 脉冲序列能否诱发超阈值反应:作为概念验证,我们在内部开发了一台能持续输出高达 250 Hz 脉冲的 TMS 机器,并在 22 只清醒大鼠身上进行了实验,以测试在 100、166 或 250 Hz 的脉冲串下是否能检测到时间相加:主要结果:实验结果表明,在55%最大刺激器输出(MSO,峰值dI/dt = 68.5 A/s at 100% MSO,脉宽 = 48 s )的TMS脉冲下,无论是单脉冲还是脉冲串都不会诱发运动反应。同样,MSO 为 65% 的单个 TMS 脉冲也未能唤起大鼠的运动反应;然而,频率为 166 和 250 Hz(但不是 100 Hz)的 TMS 脉冲串成功触发了运动反应和 MEP 信号,这表明时间累加效应取决于脉冲强度和脉冲串频率:我们提出,可以利用时间相加效应来设计下一代病灶 TMS 系统:通过以高频和阈下强度顺序驱动多个线圈,具有最显著重叠 E 场的区域会产生最大的时间相加效应,从而产生阈上反应。
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Ultra-high frequency repetitive TMS at subthreshold intensity induces suprathreshold motor response via temporal summation.

Objective.The transcranial magnetic stimulation (TMS) coil induces an electric field that diminishes rapidly upon entering the brain. This presents a challenge in achieving focal stimulation of a deep brain structure. Neuronal elements, including axons, dendrites, and cell bodies, exhibit specific time constants. When exposed to repetitive TMS pulses at a high frequency, there is a cumulative effect on neuronal membrane potentials, resulting in temporal summation. This study aims to determine whether TMS pulse train at high-frequency and subthreshold intensity could induce a suprathreshold response.Approach.As a proof of concept, we developed a TMS machine in-house that could consistently output pulses up to 250 Hz, and performed experiments on 22 awake rats to test whether temporal summation was detectable under pulse trains at 100, 166, or 250 Hz.Main results.Results revealed that TMS pulses at 55% maximum stimulator output (MSO, peak dI/dt= 68.5 A/μs at 100% MSO, pulse width = 48μs) did not induce motor responses with either single pulses or pulse trains. Similarly, a single TMS pulse at 65% MSO failed to evoke a motor response in rats; however, a train of TMS pulses at frequencies of 166 and 250 Hz, but not at 100 Hz, successfully triggered motor responses and MEP signals, suggesting a temporal summation effect dependent on both pulse intensities and pulse train frequencies.Significance.We propose that the temporal summation effect can be leveraged to design the next-generation focal TMS system: by sequentially driving multiple coils at high-frequency and subthreshold intensity, areas with the most significant overlapping E-fields undergo maximal temporal summation effects, resulting in a suprathreshold response.

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