Metaplasticity and non-invasive brain stimulation: the search for new biomarkers and directions for therapeutic neuromodulation

Q3 Multidisciplinary

Annals of Clinical and Experimental Neurology Pub Date : 2022-10-10 DOI:10.54101/acen.2022.3.9

I. Bakulin, A. Poydasheva, A. Zabirova, N. Suponeva, M. Piradov

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引用次数: 1

Abstract

Metaplasticity (plasticity of synaptic plasticity) is defined as a change in the direction or degree of synaptic plasticity in response to preceding neuronal activity. Recent advances in brain stimulation methods have enabled us to non-invasively examine cortical metaplasticity, including research in a clinical setting. According to current knowledge, non-invasive neuromodulation affects synaptic plasticity by inducing cortical processes that are similar to long-term potentiation and depression. Two stimulation blocks are usually used to assess metaplasticity priming and testing blocks. The technology of studying metaplasticity involves assessing the influence of priming on the testing protocol effect. Several dozen studies have examined the effects of different stimulation protocols in healthy persons. They found that priming can both enhance and weaken, or even change the direction of the testing protocol effect. The interaction between priming and testing stimulation depends on many factors: the direction of their effect, duration of the stimulation blocks, and the interval between them. Non-invasive brain stimulation can be used to assess aberrant metaplasticity in nervous system diseases, in order to develop new biomarkers. Metaplasticity disorders are found in focal hand dystonia, migraine with aura, multiple sclerosis, chronic disorders of consciousness, and age-related cognitive changes. The development of new, metaplasticity-based, optimized, combined stimulation protocols appears to be highly promising for use in therapeutic neuromodulation in clinical practice.

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元可塑性和非侵入性脑刺激:寻找新的生物标志物和治疗性神经调节的方向

元可塑性(突触可塑性的可塑性)被定义为响应先前神经元活动的突触可塑性方向或程度的变化。脑刺激方法的最新进展使我们能够无创地检查皮质元可塑性，包括在临床环境中的研究。根据目前的知识，非侵入性神经调节通过诱导类似于长期增强和抑郁的皮质过程来影响突触可塑性。通常使用两个刺激块来评估元塑性启动和测试块。研究元塑性的技术包括评估启动对测试协议效应的影响。几十项研究已经检验了不同刺激方案对健康人的影响。他们发现，启动既可以增强也可以削弱，甚至可以改变测试协议效应的方向。启动刺激和测试刺激之间的相互作用取决于许多因素:它们的作用方向、刺激块的持续时间以及它们之间的间隔。无创脑刺激可用于评估神经系统疾病的异常元可塑性，从而开发新的生物标志物。超可塑性障碍见于局灶性手肌张力障碍、先兆偏头痛、多发性硬化症、慢性意识障碍和与年龄相关的认知变化。新的，基于化生的，优化的，联合刺激方案的发展在临床实践中的治疗性神经调节中具有很高的前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annals of Clinical and Experimental Neurology Medicine-Neurology (clinical)

CiteScore

0.80

自引率

0.00%

发文量