A probabilistic atlas of the human motion complex built from large‐scale functional localizer data

Huang, Taicheng; Chen, Xiayu; Jiang, Jingjie; Zhen, Zonglei; Liu, Jia

doi:10.1002/hbm.24610

Cited by 16 publications

(26 citation statements)

References 49 publications

(108 reference statements)

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“…Finding that our approach generates similar ROIs to other atlases (e.g., V1-V3 in the Wang et al (2014) atlas, Benson et al (2012) atlas) and hMT+ (Huang et al 2019) is important as it illustrates that these ROIs are robust to experimental design, stimuli type, and number of subjects that were used for generating atlases, all of which varied across studies. For example, we defined hMT+ by contrasting responses to expanding and contracting low contrast concentric rings to stationary ones in 19 subjects but Huang et al (2019) defined hMT+ by contrasting responses to dots moving in several directions vs. stationary dots in 509 subjects. Despite these differences,…”

Section: Consistent Definitions Of Visual Areas Across Different Atlasesmentioning

confidence: 78%

“…To compare our atlas to the Benson atlas where there is no separation between ventral and dorsal quarterfields, we merged our dorsal and ventral V1-V3. Additionally, there is a published probabilistic atlas of CoS-places (Weiner et al 2018), and motion selective hMT+ (Huang et al 2019). We compared our surface visfAtlas to the existing surface maps by assessing their correspondence in the FreeSurfer fsaverage space.…”

Section: Comparison Of Our Visfatlas To Existing Publicly Available Amentioning

confidence: 99%

“…8E). On lateral occipitotemporal cortex we compared a recently published motion selective group area of hMT+ that has been defined using data from 509 adults (Huang et al 2019).As Huang's et al (2019) group fROI was not bounded by body-selective regions but ours was defined by maximum probability map (MPM) that takes into account the neighboring face and body-part areas, the visfAtlas is smaller than Huang's definition Nonetheless, also here, the locus of our hMT+ probabilistic map is within the hMT+ atlas published by Huang et al (2019).…”

Section: Similarities Between Previously Published Atlas Areas and Oumentioning

confidence: 99%

“…To overcome these limitations, progress in the field of cognitive neuroscience has led to the development of cortical atlases, which allow localization of visual areas in new subjects by leveraging ROI data from an independent set of typical participants (Frost and Goebel 2012; ventral-temporal cortex category selectivity: Julian et al 2012;Engell and McCarthy 2013;Zhen et al 2017a;Weiner et al 2018; visual field maps: Benson et al 2012;Wang et al 2014; motion-selective hMT: Huang et al 2019;multimodal parcellation: Glasser et al 2016; cytoarchitectonic parcellation of ventral visual cortex: Rosenke et al 2018). In addition to providing independent means to identify ROIs, this approach enables quantification of between-subject variability.…”

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confidence: 99%

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A probabilistic functional atlas of human occipito-temporal visual cortex

Rosenke

Hoof

Hurk

et al. 2020

Preprint

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1Ventral visual cortex can be divided into a variety of retinotopically as well as category-specific 2 regions. These brain areas have been the focus of a large body of functional MRI research, 3 significantly expanding our understanding of high-level visual processing. As studying these 4 regions requires accurate localization of their cortical location, it is usually necessary to perform 5 functional localizer runs on an individual subject level. These runs are costly in terms of scanning 6 time and a participant's capacity level. Moreover, certain patient populations are unable to undergo 7 such localizers, for instance the congenitally blind. In the current paper, we aimed to overcome 8 these challenges by developing a functional atlas based on localizer-and visual field mapping data 9 acquired in 20 healthy subjects. Single subject functional maps were aligned to both volume and 10 surface group space, after which a probabilistic functional group atlas was created. We 11 subsequently quantified the inter-subject variability of category-selective regions in visual cortex 12 and the specificity of each atlas region -to our knowledge the first such analyses. Additionally, 13we validated our atlas against existing atlases of retinotopic as well as category-specific regions. 14

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Section: Consistent Definitions Of Visual Areas Across Different Atlasesmentioning

confidence: 78%

Section: Comparison Of Our Visfatlas To Existing Publicly Available Amentioning

confidence: 99%

Section: Similarities Between Previously Published Atlas Areas and Oumentioning

confidence: 99%

mentioning

confidence: 99%

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A probabilistic functional atlas of human occipito-temporal visual cortex

Rosenke

Hoof

Hurk

et al. 2020

Preprint

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“…In view of these observations, we encourage researchers to use individual functional and anatomical data for designing optode layouts when possible, but when anatomical data is available and functional data is not, probabilistic functional maps constitute a promising and economic alternative. FMRI-based probabilistic functional maps of the human ventral occipital cortex 93 , human motion complex 94 , face selective areas 95,96 , finger dominance in the primary somatosensory cortex 97 or across the whole cortex 36 are freely available or available on demand.…”

Section: Recommendations For Optode Placement and The Way Forwardmentioning

confidence: 99%

Guiding functional near-infrared spectroscopy optode-layout design using individual (f)MRI data: Effects on signal quality and sensitivity

Benitez-Andonegui

Lührs

Nagels-Coune

et al. 2020

Preprint

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Designing optode layouts is an essential step for functional near-infrared spectroscopy (fNIRS) experiments as the quality of the measured signal and the sensitivity to cortical regions-of-interest depend on how optodes are arranged on the scalp. This becomes particularly relevant for fNIRS-based brain-computer interfaces (BCIs), where developing robust systems with few optodes is crucial for clinical applications. Available resources often dictate the approach researchers use for optode-layout design. Here we compared four approaches that incrementally incorporated subject-specific magnetic resonance imaging (MRI) information while participants performed mental-calculation, mental-rotation and inner-speech tasks. The literature-based approach (LIT) used a literature review to guide the optode layout design. The probabilistic approach (PROB), employed individual anatomical data and probabilistic maps of functional MRI (fMRI)-activation from an independent dataset. The individual fMRI (iFMRI) approach used individual anatomical and fMRI data, and the fourth approach used individual anatomical, functional and vascular information of the same subject (fVASC). The four approaches resulted in different optode layouts and the more informed approaches outperformed the minimally informed approach (LIT) in terms of signal quality and sensitivity. Further, PROB, iFMRI and fVASC approaches resulted in a similar outcome. We conclude that additional individual MRI data leads to a better outcome, but that not all the modalities tested here are required to achieve a robust setup. Finally, we give preliminary advice to efficiently using resources for developing robust optode layouts for BCI and neurofeedback applications.

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A probabilistic atlas of the human motion complex built from large‐scale functional localizer data

Huang

Chen

Jiang

et al. 2019

Human Brain Mapping

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Accurate motion perception is critical to dealing with the changing dynamics of our visual world. A cluster known as the human MT+ complex (hMT+) has been identified as a core region involved in motion perception. Several atlases defined based on cytoarchitecture, retinotopy, connectivity, and multimodal features include homologs of the hMT+. However, an hMT+ atlas defined directly based on this region's response for motion is still lacking. Here, we identified the hMT+ based on motion responses from functional magnetic resonance imaging (fMRI) localizer data in 509 participants and then built a probabilistic atlas of the hMT+. As a result, four main findings were revealed. First, the hMT+ showed large interindividual variability across participants. Second, the atlases stabilized when the number of participants used to build the atlas was more than 100. Third, the functional hMT+ showed good agreement with the hMT+ atlases built based on cytoarchitecture, retinotopy, and connectivity, suggesting a good structural–functional correspondence. Fourth, tests on multiple fMRI data sets acquired from independent participants, imaging parameters and paradigms revealed that the functional hMT+ showed higher sensitivity than all other atlases in ROI analysis except that connectivity and multimodal hMT+ atlases in the left hemisphere could infrequently attain comparable sensitivity to the functional atlas. Taken together, our findings reveal the benefit of using large‐scale functional localizer data to build a reliable and representative hMT+ atlas. Our atlas is freely available for download; it can be used to localize the hMT+ in individual participants when functional localizer data are not available.

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A probabilistic atlas of the human motion complex built from large‐scale functional localizer data

Cited by 16 publications

References 49 publications

A probabilistic functional atlas of human occipito-temporal visual cortex

A probabilistic functional atlas of human occipito-temporal visual cortex

Guiding functional near-infrared spectroscopy optode-layout design using individual (f)MRI data: Effects on signal quality and sensitivity

A probabilistic atlas of the human motion complex built from large‐scale functional localizer data

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