BigBrainWarp: Toolbox for integration of BigBrain 3D histology with multimodal neuroimaging

Paquola, Casey; Royer, Jessica; Lewis, Lindsay B.; Lepage, Claude; Glatard, Tristan; Wagstyl, Konrad; DeKraker, Jordan; Toussaint, Paule-J; Valk, Sofie L.; Collins, D. Louis; Khan, Ali Raza; Amunts, Katrin; Evans, Alan C.; Dickscheid, Timo; Bernhardt, Boris C.

doi:10.1101/2021.05.04.442563

Cited by 21 publications

(61 citation statements)

References 86 publications

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“…In the preceding results, we tested our hypotheses pooling all data regardless of brain region. Increasing literature, however, as well as inferences from known cytoarchitectural and connectivity differences would suggest that the responses to stimulation differ in different brain regions [24,29,35,36,48,61,[93][94][95][96]. We explored this question by specifically comparing responses when stimulation was in lateral frontal lobe, cingulate, and lateral temporal lobe (as we had the most coverage of these J o u r n a l P r e -p r o o f 34 regions; Fig.…”

Section: Brain Region Impact On Stimulation Response Sensitivity To G...mentioning

confidence: 99%

Local and distant cortical responses to single pulse intracranial stimulation in the human brain are differentially modulated by specific stimulation parameters

et al. 2022

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Section: Brain Region Impact On Stimulation Response Sensitivity To G...mentioning

confidence: 99%

Local and distant cortical responses to single pulse intracranial stimulation in the human brain are differentially modulated by specific stimulation parameters

et al. 2022

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“…Indeed, prior studies have used these datasets to relate task meta-analyses, genetic expression, and histology to markers of morphology (Valk et al, 2020;Wagstyl et al, 2020;Whitaker et al, 2016), function (Benkarim et al, 2021;Krienen et al, 2016;Margulies et al, 2016;Paquola et al, 2019), and structural connectivity (Romme et al, 2017;Vos de Wael et al, 2021). Though numerous packages exist to enable these analyses Paquola et al, 2021;Salo et al, 2020;Yarkoni et al, 2011), using and integrating these requires expertise and proficiency in their respective programming languages.…”

Section: Discussionmentioning

confidence: 99%

“…The resting-state module contextualizes neuroimaging findings using canonical networks (Yeo et al, 2011) and functional gradients (Margulies et al, 2016). The histological submodule fetches cell-body-staining intensity profiles from the BigBrain atlas (Amunts et al, 2013) at 50 different depths to extract cytoarchitectural axes (Paquola et al, 2019(Paquola et al, , 2021Vos de Wael et al, 2020).…”

Section: Tutorial 2: Context Modulementioning

confidence: 99%

BrainStat: a toolbox for brain-wide statistics and multimodal feature associations

Wael

Bayrak

Benkarim

et al. 2022

Preprint

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Analysis and interpretation of neuroimaging datasets has become a multidisciplinary endeavor, relying not only on statistical methods, but increasingly on associations with respect to other brain-derived features such as gene expression, histological data, and functional as well as cognitive architectures. Here we introduce BrainStat - a toolbox for (i) univariate and multivariate general linear models in volumetric and surface-based brain imaging datasets, and (ii) multidomain feature association of results with respect to spatial maps of post-mortem gene expression and histology, as well as task-based fMRI meta-analysis, canonical resting-state fMRI networks, and resting-state derived gradients across several common surface templates. The combination of statistics and feature associations into a turnkey toolbox offers to streamline analytical processes and accelerate cross-modal. The toolbox is implemented in both Python and MATLAB, two widely used programming languages in the neuroimaging and neuroinformatics communities. BrainStat is openly available and complemented by an expandable documentation.

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“…In the preceding results, we tested our hypotheses pooling all data regardless of brain region. Increasing literature, however, as well as inferences from known cytoarchitectural and connectivity differences would suggest that the rules for stimulation differ in different brain regions [24,28,51,60,[84][85][86][87]. We explored this question by specifically comparing responses when stimulation was in lateral prefrontal lobe, cingulate, and lateral temporal lobe (as we had the most coverage of these regions; Fig.…”

Section: Brain Region Impact On Stimulation Response Sensitivity To Grey-white Locationmentioning

confidence: 99%

“…We posit there could be an effect of being closer to the axon hillocks of large pyramidal cells in cortical layers 4-6 and that the grey-white boundary is a convergence point for multiple output neurons or is a site with a higher concentration of excitatory versus inhibitory contributions which could explain the peak local responses [83]. To test these ideas, modelling in combination with cytoarchitectonic maps are likely necessary [84,85] in addition to sampling of neural data on microscale levels [14,92,95].…”

Section: )mentioning

confidence: 99%

Impact of stimulation location relative to grey and white matter on single pulse electrical stimulation responses in the human brain

Paulk

Zelmann

Crocker

et al. 2021

Preprint

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Background: Electrical neuromodulation is an increasingly common therapy for a wide variety of neuropsychiatric diseases. Unfortunately, therapeutic efficacy is inconsistent, possibly a result of our limited understanding of the mechanisms and the massive stimulation parameter space. Objective/Hypothesis: To better understand the role different parameters play in inducing a response, we systematically examined single pulse-induced cortico-cortico evoked potentials (CCEP) as a function of stimulation amplitude, duration and location in the brain and relative to grey and white matter. Methods: We measured voltage peak amplitudes and area under the curve of intracranially recorded stimulation responses as a function of distance from the stimulation site, pulse width, current injected, location relative to grey and white matter, and brain region stimulated (N=52, n=719 stimulation sites). Results: Increasing stimulation pulse width increased response values near the stimulation location. Increasing stimulation amplitude (current) increased responses nonlinearly. Locally (<15 mm from the stimulation site), stimulation closer to the grey matter-white matter boundary induced larger responses. In contrast, for distant sites (>15 mm), white matter stimulation consistently produced larger responses than stimulation in or near grey matter. These relationships were different between cingulate, lateral prefrontal, and lateral temporal cortical stimulation. Conclusion: These results demonstrate the importance of location and stimulation parameters in inducing a specific output and indicate that a stronger local response may require stimulation in the grey-white boundary while stimulation in the white matter may be needed for network activation, suggesting that stimulation location can be tailored for a specific outcome, key to informed neuromodulatory therapy.

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BigBrainWarp: Toolbox for integration of BigBrain 3D histology with multimodal neuroimaging

Cited by 21 publications

References 86 publications

Local and distant cortical responses to single pulse intracranial stimulation in the human brain are differentially modulated by specific stimulation parameters

Local and distant cortical responses to single pulse intracranial stimulation in the human brain are differentially modulated by specific stimulation parameters

BrainStat: a toolbox for brain-wide statistics and multimodal feature associations

Impact of stimulation location relative to grey and white matter on single pulse electrical stimulation responses in the human brain

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