经颅重复磁刺激产生持久的皮质脊髓运动输出增强和大鼠脊髓结构的持久变化。

Repeated motor cortex theta-burst stimulation produces persistent strengthening of corticospinal motor output and durable spinal cord structural changes in the rat.

机构信息

Department of Molecular, Cellular, and Biomedical Sciences, Center for Discovery and Innovation, City University of New York School of Medicine, New York, NY, USA; Neuroscience Program, Graduate Center of the City University of New York, New York, NY, USA.

出版信息

Brain Stimul. 2022 Jul-Aug;15(4):1013-1022. doi: 10.1016/j.brs.2022.07.005. Epub 2022 Jul 16.

DOI:10.1016/j.brs.2022.07.005

PMID:35850438

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10164459/

Abstract

BACKGROUND

The strength of connections between motor cortex (MCX) and muscle can be augmented with a variety of stimulation protocols. Augmenting MCX-to-muscle connection strength by neuromodulation may be a way to enhance the intact motor system's capacity for acquiring motor skills and promote function after injury to strengthen spared connections. But this enhancement must be maintained for functional improvements.

OBJECTIVE

We determined if brief MCX muscle evoked potential (MEP) enhancement produced by single-block intermittent theta burst stimulation (iTBS) can be converted into a longer and structurally durable form of response enhancement with repeated daily and longer-term application.

METHODS

Electrical iTBS was delivered through an implanted MCX epidural electrode and MEPs were recorded using implanted EMG electrodes in awake naïve rats. MCX activity was modulated further using chemogenetic (DREADDs) excitation and inhibition. Corticospinal tract (CST) axons were traced and immunochemistry used to measure CST synapses.

RESULTS

A single MCX iTBS block (600 pulses) produced MEP LTP lasting ∼30-45 min. Concatenating five iTBS blocks within a 30-min session produced MEP LTP lasting 24-48 h, which could be strengthened or weakened by bidirectional MCX activity modulation. Effect duration was not changed. Finally, daily induction of this persistent MEP LTP with daily iTBS for 10-days produced MEP enhancement outlasting the stimulation period by at least 10 days, and accompanied by CST axonal outgrowth and structural changes at the CST-spinal interneuron synapse.

CONCLUSION

Our findings inform the mechanisms of iTBS and provide a framework for designing neuromodulatory strategies to promote durable enhancement of cortical motor actions.

摘要

背景

通过各种刺激方案可以增强运动皮层（MCX）和肌肉之间的连接强度。通过神经调节增强 MCX 到肌肉的连接强度可能是一种增强完整运动系统获取运动技能能力并促进受伤后功能恢复的方法，以增强剩余的连接。但是，这种增强必须保持才能实现功能改善。

目的

我们确定通过单块间歇性 theta 爆发刺激（iTBS）产生的短暂 MCX 肌肉诱发电位（MEP）增强是否可以转化为更持久和结构上更持久的反应增强形式，通过重复每日和长期应用。

方法

通过植入的 MCX 硬膜外电极传递电 iTBS，并在清醒的未处理大鼠中使用植入的肌电图电极记录 MEP。进一步使用化学遗传（DREADDs）兴奋和抑制来调节 MCX 活动。追踪皮质脊髓束（CST）轴突并使用免疫化学测量 CST 突触。

结果

单次 MCX iTBS 块（600 个脉冲）产生持续约 30-45 分钟的 MEP LTP。在 30 分钟的会议中串联五个 iTBS 块可产生持续 24-48 小时的 MEP LTP，可以通过双向 MCX 活动调节来增强或减弱。效果持续时间没有变化。最后，每日诱导这种持续的 MEP LTP，每日 iTBS 治疗 10 天，可产生至少持续 10 天的 MEP 增强，同时伴随着 CST 轴突生长和 CST-脊髓中间神经元突触的结构变化。

结论

我们的发现为 iTBS 的机制提供了信息，并为设计神经调节策略以促进皮质运动动作的持久增强提供了框架。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7258/10164459/218e5bd0a51a/nihms-1828630-f0001.jpg

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经颅重复磁刺激产生持久的皮质脊髓运动输出增强和大鼠脊髓结构的持久变化。

Repeated motor cortex theta-burst stimulation produces persistent strengthening of corticospinal motor output and durable spinal cord structural changes in the rat.

机构信息

出版信息

BACKGROUND

OBJECTIVE

METHODS

RESULTS

CONCLUSION

背景

目的

方法

结果

结论

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