TY - JOUR
T1 - A generative network model of neurodevelopmental diversity in structural brain organization
AU - The CALM Team
AU - Akarca, Danyal
AU - Vértes, Petra E.
AU - Bullmore, Edward T.
AU - Baker, Kate
AU - Gathercole, Susan E.
AU - Holmes, Joni
AU - Kievit, Rogier A.
AU - Manly, Tom
AU - Bathelt, Joe
AU - Bennett, Marc
AU - Bignardi, Giacomo
AU - Bishop, Sarah
AU - Bottacin, Erica
AU - Bridge, Lara
AU - Brkic, Diandra
AU - Bryant, Annie
AU - Butterfield, Sally
AU - Byrne, Elizabeth M.
AU - Crickmore, Gemma
AU - Dalmaijer, Edwin S.
AU - Daly, Fánchea
AU - Emery, Tina
AU - Forde, Laura
AU - Franckel, Grace
AU - Fuhrmann, Delia
AU - Gadie, Andrew
AU - Gharooni, Sara
AU - Guy, Jacalyn
AU - Hawkins, Erin
AU - Jaroslawska, Agnieszka
N1 - Publisher Copyright:
© 2021, Crown.
PY - 2021/7/9
Y1 - 2021/7/9
N2 - The formation of large-scale brain networks, and their continual refinement, represent crucial developmental processes that can drive individual differences in cognition and which are associated with multiple neurodevelopmental conditions. But how does this organization arise, and what mechanisms drive diversity in organization? We use generative network modeling to provide a computational framework for understanding neurodevelopmental diversity. Within this framework macroscopic brain organization, complete with spatial embedding of its organization, is an emergent property of a generative wiring equation that optimizes its connectivity by renegotiating its biological costs and topological values continuously over time. The rules that govern these iterative wiring properties are controlled by a set of tightly framed parameters, with subtle differences in these parameters steering network growth towards different neurodiverse outcomes. Regional expression of genes associated with the simulations converge on biological processes and cellular components predominantly involved in synaptic signaling, neuronal projection, catabolic intracellular processes and protein transport. Together, this provides a unifying computational framework for conceptualizing the mechanisms and diversity in neurodevelopment, capable of integrating different levels of analysis—from genes to cognition.
AB - The formation of large-scale brain networks, and their continual refinement, represent crucial developmental processes that can drive individual differences in cognition and which are associated with multiple neurodevelopmental conditions. But how does this organization arise, and what mechanisms drive diversity in organization? We use generative network modeling to provide a computational framework for understanding neurodevelopmental diversity. Within this framework macroscopic brain organization, complete with spatial embedding of its organization, is an emergent property of a generative wiring equation that optimizes its connectivity by renegotiating its biological costs and topological values continuously over time. The rules that govern these iterative wiring properties are controlled by a set of tightly framed parameters, with subtle differences in these parameters steering network growth towards different neurodiverse outcomes. Regional expression of genes associated with the simulations converge on biological processes and cellular components predominantly involved in synaptic signaling, neuronal projection, catabolic intracellular processes and protein transport. Together, this provides a unifying computational framework for conceptualizing the mechanisms and diversity in neurodevelopment, capable of integrating different levels of analysis—from genes to cognition.
UR - http://www.scopus.com/inward/record.url?scp=85112123565&partnerID=8YFLogxK
U2 - 10.1038/s41467-021-24430-z
DO - 10.1038/s41467-021-24430-z
M3 - Article (Academic Journal)
C2 - 34244490
AN - SCOPUS:85112123565
SN - 2041-1723
VL - 12
JO - Nature Communications
JF - Nature Communications
IS - 1
M1 - 4216
ER -