经颅磁刺激(rTMS)和电磁感知基因(EPG)的无创神经调节促进神经损伤后的可塑性。

Non-invasive neuromodulation using rTMS and the electromagnetic-perceptive gene (EPG) facilitates plasticity after nerve injury.

机构信息

Department of Biomedical Engineering, Michigan State University, East Lansing, MI, USA; The Institute of Quantitative Health Science and Engineering, Michigan State University, East Lansing, MI, USA.

The Institute of Quantitative Health Science and Engineering, Michigan State University, East Lansing, MI, USA; Department of Electrical and Computer Engineering, Michigan State University, East Lansing, MI, USA.

出版信息

Brain Stimul. 2020 Nov-Dec;13(6):1774-1783. doi: 10.1016/j.brs.2020.10.006. Epub 2020 Oct 15.

DOI:10.1016/j.brs.2020.10.006

PMID:33068795

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7722061/

Abstract

BACKGROUND

Twenty million Americans suffer from peripheral nerve injury. These patients often develop chronic pain and sensory dysfunctions. In the past decade, neuroimaging studies showed that these changes are associated with altered cortical excitation-inhibition balance and maladaptive plasticity. We tested if neuromodulation of the deprived sensory cortex could restore the cortical balance, and whether it would be effective in alleviating sensory complications.

OBJECTIVE

We tested if non-invasive repetitive transcranial magnetic stimulation (rTMS) which induces neuronal excitability, and cell-specific magnetic activation via the Electromagnetic-perceptive gene (EPG) which is a novel gene that was identified and cloned from glass catfish and demonstrated to evoke neural responses when magnetically stimulated, can restore cortical excitability.

METHODS

A rat model of forepaw denervation was used. rTMS was delivered every other day for 30 days, starting at the acute or at the chronic post-injury phase. A minimally-invasive neuromodulation via EPG was performed every day for 30 days starting at the chronic phase. A battery of behavioral tests was performed in the days and weeks following limb denervation in EPG-treated rats, and behavioral tests, fMRI and immunochemistry were performed in rTMS-treated rats.

RESULTS

The results demonstrate that neuromodulation significantly improved long-term mobility, decreased anxiety and enhanced neuroplasticity. The results identify that both acute and delayed rTMS intervention facilitated rehabilitation. Moreover, the results implicate EPG as an effective cell-specific neuromodulation approach.

CONCLUSION

Together, these results reinforce the growing amount of evidence from human and animal studies that are establishing neuromodulation as an effective strategy to promote plasticity and rehabilitation.

摘要

背景

两千四百万美国人患有周围神经损伤。这些患者常伴有慢性疼痛和感觉功能障碍。在过去十年中，神经影像学研究表明，这些变化与皮质兴奋-抑制平衡改变和适应不良性重塑有关。我们测试了剥夺感觉皮层的神经调节是否可以恢复皮质平衡，以及它是否能有效缓解感觉并发症。

目的

我们测试了非侵入性重复经颅磁刺激（rTMS）是否可以诱导神经元兴奋性，以及通过电磁感知基因（EPG）进行细胞特异性磁激活，EPG 是一种从玻璃猫鱼中鉴定和克隆的新型基因，当受到磁场刺激时可以诱发神经反应，是否可以恢复皮质兴奋性。

方法

使用大鼠前爪去神经模型。rTMS 每隔一天进行一次，共 30 天，开始于急性或慢性损伤后阶段。从慢性阶段开始，每天进行一次最小侵入性的 EPG 神经调节，共 30 天。在肢体去神经后的几天和几周内，对 EPG 治疗的大鼠进行一系列行为测试，对 rTMS 治疗的大鼠进行行为测试、 fMRI 和免疫化学测试。

结果

结果表明，神经调节显著改善了长期的运动能力，降低了焦虑并增强了神经可塑性。结果表明，急性和延迟 rTMS 干预均促进了康复。此外，结果表明 EPG 是一种有效的细胞特异性神经调节方法。

结论

总之，这些结果加强了越来越多的来自人类和动物研究的证据，这些证据确立了神经调节作为促进可塑性和康复的有效策略。

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