Low intensity repetitive transcranial magnetic stimulation modulates brain-wide functional connectivity to promote anti-correlated c-Fos expression

Moretti, Jessica; Terstege, Dylan J; Poh, Eugenia Z.; Epp, Jonathan R.; Rodger, Jennifer

doi:10.1038/s41598-022-24934-8

Cited by 18 publications

(12 citation statements)

References 71 publications

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“…To validate the E‐field distribution data, we first assessed the c‐Fos induction, a marker of neuronal activity that changes in response to magnetic stimulation, 45 in the cerebellum, the striatum, and the hippocampus. These latter two areas are critically affected in PD 46 …”

Section: Resultsmentioning

confidence: 99%

Astrocyte Responses Influence Local Effects of Whole‐Brain Magnetic Stimulation in Parkinsonian Rats

Natale,

Colella,

De Carluccio

et al. 2023

Movement Disorders

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BackgroundExcessive glutamatergic transmission in the striatum is implicated in Parkinson's disease (PD) progression. Astrocytes maintain glutamate homeostasis, protecting from excitotoxicity through the glutamate–aspartate transporter (GLAST), whose alterations have been reported in PD. Noninvasive brain stimulation using intermittent theta‐burst stimulation (iTBS) acts on striatal neurons and glia, inducing neuromodulatory effects and functional recovery in experimental parkinsonism.ObjectiveBecause PD is associated with altered astrocyte function, we hypothesized that acute iTBS, known to rescue striatal glutamatergic transmission, exerts regional‐ and cell‐specific effects through modulation of glial functions.Methods6‐Hydroxydopamine‐lesioned rats were exposed to acute iTBS, and the areas predicted to be more responsive by a biophysical, hyper‐realistic computational model that faithfully reconstructs the experimental setting were analyzed. The effects of iTBS on glial cells and motor behavior were evaluated by molecular and morphological analyses, and CatWalk and Stepping test, respectively.ResultsAs predicted by the model, the hippocampus, cerebellum, and striatum displayed a marked c‐FOS activation after iTBS, with the striatum showing specific morphological and molecular changes in the astrocytes, decreased phospho‐CREB levels, and recovery of GLAST. Striatal‐dependent motor performances were also significantly improved.ConclusionThese data uncover an unknown iTBS effect on astrocytes, advancing the understanding of the complex mechanisms involved in TMS‐mediated functional recovery. Data on numerical dosimetry, obtained with a degree of anatomical details never before considered and validated by the biological findings, provide a framework to predict the electric‐field induced in different specific brain areas and associate it with functional and molecular changes. © 2023 The Authors. Movement Disorders published by Wiley Periodicals LLC on behalf of International Parkinson and Movement Disorder Society.

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Section: Resultsmentioning

confidence: 99%

Astrocyte Responses Influence Local Effects of Whole‐Brain Magnetic Stimulation in Parkinsonian Rats

Natale,

Colella,

De Carluccio

et al. 2023

Movement Disorders

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“…One potential advantage of utilizing rotating permanent magnets is the ability to create portable, cost-effective devices compared to conventional TMS [20]. Depending on the magnet strength and rotational frequency, the E-field strengths in the sTMS, TRPMS, and Watterson multipolar systems are comparable to other forms of low field stimulation, including low field magnetic stimulation (LFMS) [27], transcranial current stimulation (tCS) [28,29], and low-intensity repetitive magnetic stimulation (LI-rMS) [30,31]. Low field stimulation has been shown to induce changes at the cellular and molecular levels.…”

Section: Discussionmentioning

confidence: 99%

Electric field characteristics of rotating permanent magnet stimulation

Robins,

Makaroff,

Dib

et al. 2024

Preprint

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Neurostimulation devices that use rotating permanent magnets are being explored for their potential therapeutic benefits in patients with psychiatric and neurological disorders. This study aims to characterize the electric field (E-field) for ten configurations of rotating magnets using finite element analysis and phantom measurements. Various configurations were modeled, including single or multiple magnets, bipolar or multipolar magnets, rotated at 10, 13.3, and 400 Hz. E-field strengths were also measured using a hollow sphere filled with a 0.9% sodium chloride solution and with a dipole probe. The E-field spatial distribution is determined by the magnets' dimensions, number of poles, direction of the magnetization, and axis of rotation, while the E-field strength is determined by the magnets' rotational frequency and magnetic field strength. The induced E-field strength on the surface of the head ranged between 0.0092 and 0.59 V/m. At the range of rotational frequencies applied, the induced E-field strengths were approximately an order or two of magnitude lower than those delivered by conventional transcranial magnetic stimulation. The impact of rotational frequency on E-field strength represents a previously unrecognized confound in clinical trials that seek to personalize stimulation frequency to individual neural oscillations and may represent a mechanism to explain some clinical trial results.

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“…This temporal delay coincides with a considerably wide tagging window, with detectable protein expression as early as 30 minutes after induction and remains elevated above baseline until 2 h after neuronal activity [50]. A wide tagging window can be beneficial in that the activity from an entire testing session can be captured, a feature which helped c-Fos become the most studied IEG for IEG-based functional connectivity analyses [51][52][53][54][55]. However, because of this wide tagging window, care must be taken to ensure that experimenters limit the extent to which they cause erroneous neuronal activity.…”

Section: Histologymentioning

confidence: 96%

Network Neuroscience Untethered: Brain-Wide Immediate Early Gene Expression for the Analysis of Functional Connectivity in Freely Behaving Animals

Terstege

Epp

2022

Biology

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Studying how spatially discrete neuroanatomical regions across the brain interact is critical to advancing our understanding of the brain. Traditional neuroimaging techniques have led to many important discoveries about the nature of these interactions, termed functional connectivity. However, in animal models these traditional neuroimaging techniques have generally been limited to anesthetized or head-fixed setups or examination of small subsets of neuroanatomical regions. Using the brain-wide expression density of immediate early genes (IEG), we can assess brain-wide functional connectivity underlying a wide variety of behavioural tasks in freely behaving animal models. Here, we provide an overview of the necessary steps required to perform IEG-based analyses of functional connectivity. We also outline important considerations when designing such experiments and demonstrate the implications of these considerations using an IEG-based network dataset generated for the purpose of this review.

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Low intensity repetitive transcranial magnetic stimulation modulates brain-wide functional connectivity to promote anti-correlated c-Fos expression

Cited by 18 publications

References 71 publications

Astrocyte Responses Influence Local Effects of Whole‐Brain Magnetic Stimulation in Parkinsonian Rats

Astrocyte Responses Influence Local Effects of Whole‐Brain Magnetic Stimulation in Parkinsonian Rats

Electric field characteristics of rotating permanent magnet stimulation

Network Neuroscience Untethered: Brain-Wide Immediate Early Gene Expression for the Analysis of Functional Connectivity in Freely Behaving Animals

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