Electrophysiological Signatures of Intrinsic Functional Connectivity Related to rTMS Treatment for Mal de Debarquement Syndrome

Cha, Yoon‐Hee; Shou, Guofa; Gleghorn, Diamond; Doudican, Benjamin; Yuan, Han; Ding, Lei

doi:10.1007/s10548-018-0671-6

Cited by 16 publications

(20 citation statements)

References 75 publications

(104 reference statements)

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“…Simultaneously acquired fMRI-EEG data on individuals with MdDS have provided cross-modal validation of biomarkers found separately, showing that brain network-level changes associated with clinical effects are consistent across modalities of different temporal resolutions (49,69,70,(72)(73)(74). Our data showed that after rTMS at DLPFC, EEG synchronization changes in medial frontal gyrus were associated with fMRI-measured connectivity changes involving deeper cortical structures, particularly in a network that includes the entorhinal cortex and right IPL, indicating that the modulatory effect of rTMS is at least partially related to reducing the connectivity within the DMN (49,73).…”

Section: Simultaneous Functional Magnetic Resonance Imaging-electroenmentioning

confidence: 99%

“…Measurement of this connectivity was reflected through independent component phase coherence (ICPC), a calculation of synchronicity at individual frequency bands (delta, theta, low alpha, high alpha, beta, and gamma) on an independent component level rather than an individual channel level ( 69 ). ICPC calculations on 128-channel EEG data collected pre and post rTMS have shown distinct differences in synchronizations across independent component regions and frequencies ( 69 , 70 ). In general, reduction in ICPC in the delta, high alpha, beta, and gamma bands were noted with symptom improvement, whereas increase in ICPC was noted in the low alpha band ( Figure 6A ).…”

Section: Electroencephalographymentioning

confidence: 99%

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Neuroimaging Markers of Mal de Débarquement Syndrome

2021

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Mal de débarquement syndrome (MdDS) is a motion-induced disorder of oscillating vertigo that persists after the motion has ceased. The neuroimaging characteristics of the MdDS brain state have been investigated with studies on brain metabolism, structure, functional connectivity, and measurements of synchronicity. Baseline metabolism and resting-state functional connectivity studies indicate that a limbic focus in the left entorhinal cortex and amygdala may be important in the pathology of MdDS, as these structures are hypermetabolic in MdDS and exhibit increased functional connectivity to posterior sensory processing areas and reduced connectivity to the frontal and temporal cortices. Both structures are tunable with periodic stimulation, with neurons in the entorhinal cortex required for spatial navigation, acting as a critical efferent pathway to the hippocampus, and sending and receiving projections from much of the neocortex. Voxel-based morphometry measurements have revealed volume differences between MdDS and healthy controls in hubs of multiple resting-state networks including the default mode, salience, and executive control networks. In particular, volume in the bilateral anterior cingulate cortices decreases and volume in the bilateral inferior frontal gyri/anterior insulas increases with longer duration of illness. Paired with noninvasive neuromodulation interventions, functional neuroimaging with functional magnetic resonance imaging (fMRI), electroencephalography (EEG), and simultaneous fMRI-EEG have shown changes in resting-state functional connectivity that correlate with symptom modulation, particularly in the posterior default mode network. Reduced parieto-occipital connectivity with the entorhinal cortex and reduced long-range fronto-parieto-occipital connectivity correlate with symptom improvement. Though there is a general theme of desynchronization correlating with reduced MdDS symptoms, the prediction of optimal stimulation parameters for noninvasive brain stimulation in individuals with MdDS remains a challenge due to the large parameter space. However, the pairing of functional neuroimaging and noninvasive brain stimulation can serve as a probe into the biological underpinnings of MdDS and iteratively lead to optimal parameter space identification.

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Section: Simultaneous Functional Magnetic Resonance Imaging-electroenmentioning

confidence: 99%

Section: Electroencephalographymentioning

confidence: 99%

Neuroimaging Markers of Mal de Débarquement Syndrome

2021

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“…36 Markers of symptom improvement after DLPFC stimulation include a reduction in connectivity within the posterior default mode network, specifically a reduction in connectivity with the entorhinal cortex. [37][38][39] Moreover, symptom improvement was characterized by reduced longrange connectivity (frontoparietal) in the high α À band (11)(12)(13) and β-bands (14-30 Hz), and an increase in connectivity in the low α-band (8-10 Hz). 39…”

Section: Theory 2: Entrainment and Activation Of Central Oscillatorsmentioning

confidence: 99%

“…[37][38][39] Moreover, symptom improvement was characterized by reduced longrange connectivity (frontoparietal) in the high α À band (11)(12)(13) and β-bands (14-30 Hz), and an increase in connectivity in the low α-band (8-10 Hz). 39…”

Section: Theory 2: Entrainment and Activation Of Central Oscillatorsmentioning

confidence: 99%

Mal de Debarquement Syndrome

Saha

Cha

2020

Semin Neurol

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Mal de debarquement syndrome (MdDS) is a disorder of persistent vertigo characterized by a feeling of oscillation such as rocking, bobbing, or swaying. It is triggered by passive motion, typically by exposure to water, air, or land transportation. This syndrome affects middle-aged individuals who are predominantly women. MdDS presents as a balance disorder that carries significant risk of morbidity due to both the direct effects of balance impairment and associated symptoms of fatigue, cognitive slowing, and visual motion intolerance. The Barany Society will be publishing criteria for diagnosing persistent MdDS. In addition, more insight has been gained into the pathophysiology of MdDS, with current hypotheses pointing to a cerebral and cerebellar basis. Treatments have expanded beyond medication trials, and now include the use of noninvasive brain stimulation and readaptation of the vestibulo-ocular reflex.

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“…Weak rTMS-induced electric fields produce neural entrainment in humans Ando et al (2018) RMT 90 n/r 3 Bai et al (2016) RMT 90 n/r 4 Bharath et al 2017RMT 90 n/r 5 Cao et al (2018) RMT 100 44.5 6 Capotosto et al (2017) RMT 100 n/r 7 Cha et al (2018) RMT 110 n/r 8 Chen et al (2017) RMT 110 n/r 9 D'Agata et al 2016RMT 80 n/r 10 Daltrozzo et al (2016) RMT 90 n/r 11 DelFelice et al 2016RMT 100 58.6/61.9 12 DiGiacomo et al 2018RMT 80 47.4 13 Emrich et al 2017RMT 110 72 14 Fisher et al (2018) RMT 90 n/r 15 Gongora et al 2016RMT 80 47.4 16 He et al 2018RMT 100 n/r 17 Hunter et al 2018RMT 80-120 n/r 18 Jin et al 2017RMT 90 n/r 19 Kamp et al (2016) RMT 110 n/r 20 Karton et al (2017) vMT 80 n/r 21 Kazemi et al (2016) RMT 100/120 n/r 22 Kazemi et al (2018) RMT 100/120 n/r 23 Keuper et al (2018) FXD i/r 50 24 Kim et al (2016) vMT 110 n/r 25 Kito et al (2017) MT 120 n/r 26 Koch et al (2018) RMT 110 60. 8 27 Li et al (2016) MT 100 n/r 28 RMT 110 n/r 29 RMT 110 n/r 30 Lowe et al (2018) RMT 80 52/53 31 Lozeron et al (2017) RMT 80 n/r 32 Moebius et al (2017) RMT 110 n/r 33 Nathou et al (2018) RMT 80 n/r 34 Nicolo et al (2016) vMT 90 n/r 35 Noda et al (2017) RMT 95 82.…”

Section: Supplemental Informationmentioning

confidence: 99%

Weak rTMS-induced electric fields produce neural entrainment in humans

Zmeykina¹,

Mittner²,

Paulus³

et al. 2019

Preprint

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Repetitive transcranial magnetic stimulation (rTMS) is a potent tool for modulating endogenous oscillations in humans. The current standard dosing method for rTMS defines the electric field strength only indirectly. A better characterization of the electric field strength induced by a given rTMS protocol is necessary in order to improve the understanding of the neural mechanisms of rTMS. In this study we used a novel approach, in which individualized prospective computational modeling of the induced electric field guided the choice of stimulation intensity. We consistently found that rhythmic rTMS protocols increased neural synchronization in the posterior alpha frequency band when measured simultaneously with scalp electroencephalography. We observed this effect already at electric field strengths of roughly half the lowest conventional dose, which is 80% of the resting motor threshold. We conclude that rTMS can induce immediate electrophysiological effects at much weaker electric field strengths than previously thought.

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Electrophysiological Signatures of Intrinsic Functional Connectivity Related to rTMS Treatment for Mal de Debarquement Syndrome

Cited by 16 publications

References 75 publications

Neuroimaging Markers of Mal de Débarquement Syndrome

Neuroimaging Markers of Mal de Débarquement Syndrome

Mal de Debarquement Syndrome

Weak rTMS-induced electric fields produce neural entrainment in humans

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