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How different priming stimulations affect the corticospinal excitability induced by noninvasive brain stimulation techniques: a systematic review and meta-analysis

  • Maryam Hassanzahraee ORCID logo EMAIL logo , Maryam Zoghi and Shapour Jaberzadeh
Published/Copyright: March 31, 2018
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Reviews in the Neurosciences
From the journal Reviews in the Neurosciences Volume 29 Issue 8

Abstract

Noninvasive brain stimulation (NIBS) techniques could induce changes in corticospinal excitability (CSE) and neuroplasticity. These changes could be affected by different factors, including having a session of stimulation called the ‘priming’ protocol before the main stimulation session called the ‘test’ protocol. Literature indicates that a priming protocol could affect the activity of postsynaptic neurons, form a neuronal history, and then modify the expected effects of the test protocol on CSE indicated by the amplitude of transcranial magnetic stimulation-induced motor-evoked potentials. This prior history affects a threshold to activate the necessary mechanism stabilizing the neuronal activity within a useful dynamic range. For studying the effects of this history and related metaplasticity mechanisms in the human primary motor cortex (M1), priming-test protocols are successfully employed. Thirty-two studies were included in this review to investigate how different priming protocols could affect the induced effects of a test protocol on CSE in healthy individuals. The results showed that if the history of synaptic activity were high or low enough to displace the threshold, the expected effects of the test protocol would be the reverse. This effect reversal is regulated by homeostatic mechanisms. On the contrary, the effects of the test protocol would not be the reverse, and at most we experience a prolongation of the lasting effects if the aforementioned history is not enough to displace the threshold. This effect prolongation is mediated by nonhomeostatic mechanisms. Therefore, based on the characteristics of priming-test protocols and the interval between them, the expected results of priming-test protocols would be different. Moreover, these findings could shed light on the different mechanisms of metaplasticity involved in NIBS. It helps us understand how we can improve the expected outcomes of these techniques in clinical approaches.

Keywords: motor-evoked potentials; plasticity; primary motor cortex; priming; tDCS; TMS

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Received: 2017-12-23
Accepted: 2018-01-12
Published Online: 2018-03-31
Published in Print: 2018-11-27

©2018 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/revneuro-2017-0111
Keywords for this article
motor-evoked potentials; plasticity; primary motor cortex; priming; tDCS; TMS

Articles in the same Issue

  1. Frontmatter
  2. Roles of the exon junction complex components in the central nervous system: a mini review
  3. Metabolic regulation of synaptic activity
  4. CD200-, CX3CL1-, and TREM2-mediated neuron-microglia interactions and their involvements in Alzheimer’s disease
  5. Rab23 and developmental disorders
  6. When your face describes your memories: facial expressions during retrieval of autobiographical memories
  7. Balo’s concentric sclerosis: an update and comprehensive literature review
  8. How different priming stimulations affect the corticospinal excitability induced by noninvasive brain stimulation techniques: a systematic review and meta-analysis
  9. Corrigendum
  10. Corrigendum to: The functional role of all postsynaptic potentials examined from a first-person frame of reference
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