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. FairAlice M. Graham

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

1 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",

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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

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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

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Keywords

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