Dysfunctional white‐matter networks in medicated and unmedicated benign epilepsy with centrotemporal spikes

Jiang, Yuchao; Li, Song; Li, Xuan; Zhang, Yaodan; Chen, Yan; Jiang, Sisi; Hou, Changyue; Yao, Dezhong; Wang, Xiaoming; Luo, Cheng

doi:10.1002/hbm.24584

Cited by 69 publications

(69 citation statements)

References 63 publications

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“…Taken together, these findings suggest that there are no fundamental barriers or direct sources of evidence against the possibility of detecting neural activities of BOLD‐fMRI in WM (Gawryluk, Mazerolle, & D'Arcy, ). To date, many psychiatric and neurological disorders are characterized by WM functional abnormalities (Ji et al, ; Jiang et al, ; Jiang et al, ; Wang et al, ). It is therefore important to explore WM functional networks to allow for fMRI‐based investigations of WM brain disorders, such as multiple sclerosis (He et al, ), and WM dementia (Filley, ), which may allow further insight into our understanding of the pathological mechanisms of different neurological diseases.…”

Section: Discussionmentioning

confidence: 99%

“…More recently, Ji et al found that patients with Parkinson's disease showed increased small‐worldness in the WM functional network (Ji et al, ). Moreover, brain function profiles of WM function, including power spectra, coupling of WM and GM functional connectivity were found to be disrupted in various brain disorders, such as pontine stroke, Alzheimer's disease, and epilepsy (Jiang et al, ; Makedonov, Chen, Masellis, & MacIntosh, ; Wang et al, ). However, such previous studies focused on the extant functional modules and large‐scale networks in WM; used relatively small sample sizes; and failed to offer direct evidence for the different roles played by functional connectomes within WM and GM.…”

Section: Introductionmentioning

confidence: 99%

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Exploring the functional connectome in white matter

Biswal

Wang

et al. 2019

Human Brain Mapping

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A major challenge in neuroscience is understanding how brain function emerges from the connectome. Most current methods have focused on quantifying functional connectomes in gray‐matter (GM) signals obtained from functional magnetic resonance imaging (fMRI), while signals from white‐matter (WM) have generally been excluded as noise. In this study, we derived a functional connectome from WM resting‐state blood‐oxygen‐level‐dependent (BOLD)‐fMRI signals from a large cohort (n = 488). The WM functional connectome exhibited weak small‐world topology and nonrandom modularity. We also found a long‐term (i.e., over 10 months) topological reliability, with topological reproducibility within different brain parcellation strategies, spatial distance effect, global and cerebrospinal fluid signals regression or not. Furthermore, the small‐worldness was positively correlated with individuals' intelligence values (r = .17, pcorrected = .0009). The current findings offer initial evidence using WM connectome and present additional measures by which to uncover WM functional information in both healthy individuals and in cases of clinical disease.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Exploring the functional connectome in white matter

Biswal

Wang

et al. 2019

Human Brain Mapping

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“…These and other relevant contributions were included in a recent Perspective by Grajauskas et al (2019) who argue strongly that WM activity should not be treated as a nuisance regressor but instead be recognized as important in analyses of brain function. Moreover, an increasing number of studies have reported that alterations of WM networks are associated with brain disorders including schizophrenia, Parkinson’s disease and epilepsy (; Ji et al, 2019 ; Jiang et al, 2019 , 2018 ). Taken together, these findings indicate that WM-GM and WM-WM correlations reveal an underlying organization and suggest further investigations are justified of the possible contributions of WM signals to the identification of well-established brain networks that by convention consist of GM alone.…”

Section: Introductionmentioning

confidence: 99%

Functional engagement of white matter in resting-state brain networks

Gao

et al. 2020

NeuroImage

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The topological characteristics of functional networks, derived from measurements of resting-state connectivity in gray matter (GM), are associated with individual cognitive abilities or specific dysfunctions. However, blood oxygen level-dependent (BOLD) signals in white matter (WM) are usually ignored or even regressed out as nuisance factors in the data analyses that underlie network models. Recent studies have demonstrated reliable detection of WM BOLD signals and imply these reflect associated neural activities. Here we evaluate quantitatively the contributions of individual WM voxels to the identification of functional networks, which we term their engagement (or conceptually, their importance). We quantify the engagement by measuring the reductions of connectivity, produced by ignoring the signal fluctuations within each WM voxel, with respect to both the entire network (global) or a single GM node (local). We observed highly reproducible spatial distributions of global engagement maps, as well as a trend toward increased relevance of deep WM voxels at delayed times. Local engagement maps exhibit homogeneous spatial distributions with respect to internal nodes that constitute a well-recognized sub-functional network, but inhomogeneous distributions with respect to other nodes. WM voxels show distinct distributions of engagement depending on their anatomical locations. These findings demonstrate the important role of WM in network modeling, thus supporting the need for changes of conventional views that WM signal variations represent only physiological noise.

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“…In the 30-80 Hz band, the PCC region was inactivated, while in the 80-250 Hz band, the MFC region was inactivated. Some studies suggest that frequent interictal spike discharges, especially during sleep, may interfere with the development of white matter in children, thereby causing changes in the neuromagnetic field [13,39]. During the resting state, the brain is active in an organized way, and this active network is called the default mode network (DMN), which includes the PCC, the dorsal medial prefrontal cortex (middle frontal gyrus, superior frontal gyrus), dorsal anterior cingulate gyrus, and bilateral angular gyrus [40].…”

Section: Source Localizationmentioning

confidence: 99%

The relationship between neuromagnetic activity and cognitive function in benign childhood epilepsy with centrotemporal spikes

Sun

Niu

et al. 2020

Epilepsy & Behavior

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Our aim was to explore the pathophysiological mechanism of cognitive function changes in early untreated children with benign childhood epilepsy with centrotemporal spikes (BECTS). Methods: Magnetoencephalography (MEG) was performed in 33 children with BECTS and 18 healthy children. Wechsler Intelligence Scale for Children, fourth edition (WISC-IV) was used to divide children with BECTS into two groups. Normal cognitive function was defined as a full-scale intelligence quotient (FSIQ) of N 80, while decreased cognitive function was defined as a FSIQ of b 80. Accumulated source imaging was used to evaluate the neuromagnetic source activity in multifrequency bands. Results: Of the 33 patients with early untreated BECTS, a total of 17 had a FSIQ of b 80 and 16 had FSIQ of N 80. The course of epilepsy and number of seizures in the FSIQ b80 group were higher than that in the FSIQ N 80 group. Our MEG results showed that in the 4-8 Hz frequency band, both patient groups had inactivation of the posterior cingulate cortex (PCC) region compared with the healthy control group. In the 30-80 Hz frequency band, the FSIQ b 80 group showed inactivation of the PCC region compared with both the healthy control group and the FSIQ N 80 group. In the 80-250 Hz frequency band, the FSIQ b80 group had inactivated of the medial frontal cortex (MFC) region compared with the healthy control group. In the 30-80 Hz frequency band, the strength of neuromagnetic source in patients with BECTS with FSIQ b80 was higher than that in the FSIQ N 80 group and the healthy control group. Conclusions: The magnetic source inactivation of the MFC and PCC regions during the interictal time may be the reason for cognitive decline in early untreated children with BECTS. Children with BECTS with cognitive decline had a longer course of epilepsy and more seizures. The magnetic source localization in the 4-8 Hz frequency band may be a new imaging marker for the diagnosis of new BECTS.

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Dysfunctional white‐matter networks in medicated and unmedicated benign epilepsy with centrotemporal spikes

Cited by 69 publications

References 63 publications

Exploring the functional connectome in white matter

Exploring the functional connectome in white matter

Functional engagement of white matter in resting-state brain networks

The relationship between neuromagnetic activity and cognitive function in benign childhood epilepsy with centrotemporal spikes

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