Towards personalized precision functional mapping in infancy

Lucille A. Moore; Robert J.M. Hermosillo; Eric Feczko; Julia Moser; Sanju Koirala; Madeleine C. Allen; Claudia Buss; Greg Conan; Anthony C. Juliano; Mollie Marr; Oscar Miranda-Dominguez; Michael Mooney; Michael Myers; Jerod Rasmussen; Cynthia Rogers; Christopher D. Smyser; Kathy Snider; Chad Sylvester; Elina Thomas; Damien A. Fair; Alice M. Graham

doi:10.1162/imag_a_00165

Towards personalized precision functional mapping in infancy

Lucille A. Moore
, Robert J.M. Hermosillo
, Eric Feczko
, Julia Moser
, Sanju Koirala
, Madeleine C. Allen
, Claudia Buss
, Greg Conan
, Anthony C. Juliano
, Mollie Marr
, Oscar Miranda-Dominguez
, Michael Mooney
, Michael Myers
, Jerod Rasmussen
, Cynthia Rogers
, Christopher D. Smyser
, Kathy Snider
, Chad Sylvester
, Elina Thomas
, Damien A. Fair

Alice M. Graham

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

3 Scopus citations

Abstract

The precise network topology of functional brain systems is highly specific to individuals and undergoes dramatic changes during critical periods of development. Large amounts of high-quality resting state data are required to investigate these individual differences, but are difficult to obtain in early infancy. Using the template matching method, we generated a set of infant network templates to use as priors for individualized functional resting-state network mapping in two independent neonatal datasets with extended acquisition of resting-state functional MRI (fMRI) data. We show that template matching detects all major adult resting-state networks in individual infants and that the topology of these resting-state network maps is individual-specific. Interestingly, there was no plateau in within-subject network map similarity with up to 25 minutes of resting-state data, suggesting that the amount and/or quality of infant data required to achieve stable or high-precision network maps is higher than adults. These findings are a critical step towards personalized precision functional brain mapping in infants, which opens new avenues for clinical applicability of resting-state fMRI and potential for robust prediction of how early functional connectivity patterns relate to subsequent behavioral phenotypes and health outcomes.

Original language	English
Pages (from-to)	1-20
Number of pages	20
Journal	Imaging Neuroscience
Volume	2
DOIs	https://doi.org/10.1162/imag_a_00165
State	Published - May 10 2024

Keywords

brain development
infants
precision network mapping
resting-state fMRI
resting-state functional brain networks
template matching

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10.1162/imag_a_00165

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Moore, L. A., Hermosillo, R. J. M., Feczko, E., Moser, J., Koirala, S., Allen, M. C., Buss, C., Conan, G., Juliano, A. C., Marr, M., Miranda-Dominguez, O., Mooney, M., Myers, M., Rasmussen, J., Rogers, C., Smyser, C. D., Snider, K., Sylvester, C., Thomas, E., ... Graham, A. M. (2024). Towards personalized precision functional mapping in infancy. Imaging Neuroscience, 2, 1-20. https://doi.org/10.1162/imag_a_00165

@article{f42e27a7ba004230ba2596bd7a9a9cfe,

title = "Towards personalized precision functional mapping in infancy",

abstract = "The precise network topology of functional brain systems is highly specific to individuals and undergoes dramatic changes during critical periods of development. Large amounts of high-quality resting state data are required to investigate these individual differences, but are difficult to obtain in early infancy. Using the template matching method, we generated a set of infant network templates to use as priors for individualized functional resting-state network mapping in two independent neonatal datasets with extended acquisition of resting-state functional MRI (fMRI) data. We show that template matching detects all major adult resting-state networks in individual infants and that the topology of these resting-state network maps is individual-specific. Interestingly, there was no plateau in within-subject network map similarity with up to 25 minutes of resting-state data, suggesting that the amount and/or quality of infant data required to achieve stable or high-precision network maps is higher than adults. These findings are a critical step towards personalized precision functional brain mapping in infants, which opens new avenues for clinical applicability of resting-state fMRI and potential for robust prediction of how early functional connectivity patterns relate to subsequent behavioral phenotypes and health outcomes.",

keywords = "brain development, infants, precision network mapping, resting-state fMRI, resting-state functional brain networks, template matching",

author = "Moore, \{Lucille A.\} and Hermosillo, \{Robert J.M.\} and Eric Feczko and Julia Moser and Sanju Koirala and Allen, \{Madeleine C.\} and Claudia Buss and Greg Conan and Juliano, \{Anthony C.\} and Mollie Marr and Oscar Miranda-Dominguez and Michael Mooney and Michael Myers and Jerod Rasmussen and Cynthia Rogers and Smyser, \{Christopher D.\} and Kathy Snider and Chad Sylvester and Elina Thomas and Fair, \{Damien A.\} and Graham, \{Alice M.\}",

note = "Publisher Copyright: {\textcopyright} 2024 Massachusetts Institute of Technology. Published under a Creative Commons Attribution 4.0 International (CC BY 4.0) license.",

year = "2024",

month = may,

day = "10",

doi = "10.1162/imag\_a\_00165",

language = "English",

volume = "2",

pages = "1--20",

journal = "Imaging Neuroscience",

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Moore, LA, Hermosillo, RJM, Feczko, E, Moser, J, Koirala, S, Allen, MC, Buss, C, Conan, G, Juliano, AC, Marr, M, Miranda-Dominguez, O, Mooney, M, Myers, M, Rasmussen, J, Rogers, C , Smyser, CD, Snider, K, Sylvester, C, Thomas, E, Fair, DA & Graham, AM 2024, 'Towards personalized precision functional mapping in infancy', Imaging Neuroscience, vol. 2, pp. 1-20. https://doi.org/10.1162/imag_a_00165

TY - JOUR

T1 - Towards personalized precision functional mapping in infancy

AU - Moore, Lucille A.

AU - Hermosillo, Robert J.M.

AU - Feczko, Eric

AU - Moser, Julia

AU - Koirala, Sanju

AU - Allen, Madeleine C.

AU - Buss, Claudia

AU - Conan, Greg

AU - Juliano, Anthony C.

AU - Marr, Mollie

AU - Miranda-Dominguez, Oscar

AU - Mooney, Michael

AU - Myers, Michael

AU - Rasmussen, Jerod

AU - Rogers, Cynthia

AU - Smyser, Christopher D.

AU - Snider, Kathy

AU - Sylvester, Chad

AU - Thomas, Elina

AU - Fair, Damien A.

AU - Graham, Alice M.

PY - 2024/5/10

Y1 - 2024/5/10

N2 - The precise network topology of functional brain systems is highly specific to individuals and undergoes dramatic changes during critical periods of development. Large amounts of high-quality resting state data are required to investigate these individual differences, but are difficult to obtain in early infancy. Using the template matching method, we generated a set of infant network templates to use as priors for individualized functional resting-state network mapping in two independent neonatal datasets with extended acquisition of resting-state functional MRI (fMRI) data. We show that template matching detects all major adult resting-state networks in individual infants and that the topology of these resting-state network maps is individual-specific. Interestingly, there was no plateau in within-subject network map similarity with up to 25 minutes of resting-state data, suggesting that the amount and/or quality of infant data required to achieve stable or high-precision network maps is higher than adults. These findings are a critical step towards personalized precision functional brain mapping in infants, which opens new avenues for clinical applicability of resting-state fMRI and potential for robust prediction of how early functional connectivity patterns relate to subsequent behavioral phenotypes and health outcomes.

AB - The precise network topology of functional brain systems is highly specific to individuals and undergoes dramatic changes during critical periods of development. Large amounts of high-quality resting state data are required to investigate these individual differences, but are difficult to obtain in early infancy. Using the template matching method, we generated a set of infant network templates to use as priors for individualized functional resting-state network mapping in two independent neonatal datasets with extended acquisition of resting-state functional MRI (fMRI) data. We show that template matching detects all major adult resting-state networks in individual infants and that the topology of these resting-state network maps is individual-specific. Interestingly, there was no plateau in within-subject network map similarity with up to 25 minutes of resting-state data, suggesting that the amount and/or quality of infant data required to achieve stable or high-precision network maps is higher than adults. These findings are a critical step towards personalized precision functional brain mapping in infants, which opens new avenues for clinical applicability of resting-state fMRI and potential for robust prediction of how early functional connectivity patterns relate to subsequent behavioral phenotypes and health outcomes.

KW - brain development

KW - infants

KW - precision network mapping

KW - resting-state fMRI

KW - resting-state functional brain networks

KW - template matching

UR - https://www.scopus.com/pages/publications/105007038494

U2 - 10.1162/imag_a_00165

DO - 10.1162/imag_a_00165

M3 - Article

C2 - 40083644

AN - SCOPUS:105007038494

SN - 2837-6056

VL - 2

SP - 1

EP - 20

JO - Imaging Neuroscience

JF - Imaging Neuroscience

ER -

Towards personalized precision functional mapping in infancy

Abstract

Keywords

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