Parcellating an individual subject's cortical and subcortical brain structures using snowball sampling of resting-state correlations

Gagan S. Wig; Timothy O. Laumann; Alexander L. Cohen; Jonathan D. Power; Steven M. Nelson; Matthew F. Glasser; Francis M. Miezin; Abraham Z. Snyder; Bradley L. Schlaggar; Steven E. Petersen

doi:10.1093/cercor/bht056

Parcellating an individual subject's cortical and subcortical brain structures using snowball sampling of resting-state correlations

Gagan S. Wig, Timothy O. Laumann, Alexander L. Cohen, Jonathan D. Power, Steven M. Nelson, Matthew F. Glasser, Francis M. Miezin, Abraham Z. Snyder, Bradley L. Schlaggar, Steven E. Petersen

Research output: Contribution to journal › Article › peer-review

90 Scopus citations

Abstract

We describe methods for parcellating an individual subject's cortical and subcortical brain structures using resting-state functional correlations (RSFCs). Inspired by approaches from social network analysis, we first describe the application of snowball sampling on RSFC data (RSFC-Snowballing) to identify the centers of cortical areas, subdivisions of subcortical nuclei, and the cerebellum. RSFC-Snowballing parcellation is then compared with parcellation derived from identifying locations where RSFC maps exhibit abrupt transitions (RSFC-Boundary Mapping). RSFC-Snowballing and RSFC-Boundary Mapping largely complement one another, but also provide unique parcellation information; together, the methods identify independent entities with distinct functional correlations across many cortical and subcortical locations in the brain. RSFC parcellation is relatively reliable within a subject scanned across multiple days, and while the locations of many area centers and boundaries appear to exhibit considerable overlap across subjects, there is also cross-subject variability - reinforcing the motivation to parcellate brains at the level of individuals. Finally, examination of a large meta-analysis of taskevoked functional magnetic resonance imaging data reveals that area centers defined by task-evoked activity exhibit correspondence with area centers defined by RSFC-Snowballing. This observation provides important evidence for the ability of RSFC to parcellate broad expanses of an individual's brain into functionally meaningful units.

Original language	English (US)
Pages (from-to)	2036-2054
Number of pages	19
Journal	Cerebral Cortex
Volume	24
Issue number	8
DOIs	https://doi.org/10.1093/cercor/bht056
State	Published - Aug 2014
Externally published	Yes

Bibliographical note

Funding Information:
This work was supported by an Institute for Aging Postdoctoral Fellowship from the Canadian Institute for Health Research (G.S.W.), P50NS006833 and P30NS048056 (A.Z.S.), NIH R01HD057076 (B.L.S.), NIH NS61144, and a McDonnell Foundation Collaborative Action Award (S.E.P.), and the Human Connectome Project (1U54MH091657) from the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research. Funding to pay the Open Access publication charges for this article was provided by a McDonnell Foundation Collaborative Action Award (S.E.P.).

Keywords

Boundary mapping
Brain area parcellation
Brain networks
Individual differences
Resting-state functional correlations
Snowball sampling

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title = "Parcellating an individual subject's cortical and subcortical brain structures using snowball sampling of resting-state correlations",

abstract = "We describe methods for parcellating an individual subject's cortical and subcortical brain structures using resting-state functional correlations (RSFCs). Inspired by approaches from social network analysis, we first describe the application of snowball sampling on RSFC data (RSFC-Snowballing) to identify the centers of cortical areas, subdivisions of subcortical nuclei, and the cerebellum. RSFC-Snowballing parcellation is then compared with parcellation derived from identifying locations where RSFC maps exhibit abrupt transitions (RSFC-Boundary Mapping). RSFC-Snowballing and RSFC-Boundary Mapping largely complement one another, but also provide unique parcellation information; together, the methods identify independent entities with distinct functional correlations across many cortical and subcortical locations in the brain. RSFC parcellation is relatively reliable within a subject scanned across multiple days, and while the locations of many area centers and boundaries appear to exhibit considerable overlap across subjects, there is also cross-subject variability - reinforcing the motivation to parcellate brains at the level of individuals. Finally, examination of a large meta-analysis of taskevoked functional magnetic resonance imaging data reveals that area centers defined by task-evoked activity exhibit correspondence with area centers defined by RSFC-Snowballing. This observation provides important evidence for the ability of RSFC to parcellate broad expanses of an individual's brain into functionally meaningful units.",

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author = "Wig, {Gagan S.} and Laumann, {Timothy O.} and Cohen, {Alexander L.} and Power, {Jonathan D.} and Nelson, {Steven M.} and Glasser, {Matthew F.} and Miezin, {Francis M.} and Snyder, {Abraham Z.} and Schlaggar, {Bradley L.} and Petersen, {Steven E.}",

note = "Funding Information: This work was supported by an Institute for Aging Postdoctoral Fellowship from the Canadian Institute for Health Research (G.S.W.), P50NS006833 and P30NS048056 (A.Z.S.), NIH R01HD057076 (B.L.S.), NIH NS61144, and a McDonnell Foundation Collaborative Action Award (S.E.P.), and the Human Connectome Project (1U54MH091657) from the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research. Funding to pay the Open Access publication charges for this article was provided by a McDonnell Foundation Collaborative Action Award (S.E.P.).",

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AU - Snyder, Abraham Z.

AU - Schlaggar, Bradley L.

AU - Petersen, Steven E.

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N2 - We describe methods for parcellating an individual subject's cortical and subcortical brain structures using resting-state functional correlations (RSFCs). Inspired by approaches from social network analysis, we first describe the application of snowball sampling on RSFC data (RSFC-Snowballing) to identify the centers of cortical areas, subdivisions of subcortical nuclei, and the cerebellum. RSFC-Snowballing parcellation is then compared with parcellation derived from identifying locations where RSFC maps exhibit abrupt transitions (RSFC-Boundary Mapping). RSFC-Snowballing and RSFC-Boundary Mapping largely complement one another, but also provide unique parcellation information; together, the methods identify independent entities with distinct functional correlations across many cortical and subcortical locations in the brain. RSFC parcellation is relatively reliable within a subject scanned across multiple days, and while the locations of many area centers and boundaries appear to exhibit considerable overlap across subjects, there is also cross-subject variability - reinforcing the motivation to parcellate brains at the level of individuals. Finally, examination of a large meta-analysis of taskevoked functional magnetic resonance imaging data reveals that area centers defined by task-evoked activity exhibit correspondence with area centers defined by RSFC-Snowballing. This observation provides important evidence for the ability of RSFC to parcellate broad expanses of an individual's brain into functionally meaningful units.

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Parcellating an individual subject's cortical and subcortical brain structures using snowball sampling of resting-state correlations

Abstract

Bibliographical note

Keywords

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