An expanding manifold in transmodal regions characterizes adolescent reconfiguration of structural connectome organization

Park, Bo‐yong; Bethlehem, Richard A.I.; Paquola, Casey; Larivière, Sara; Cruces, Raúl R.; Wael, Reinder Vos de; Bullmore, Edward T.; Bernhardt, Boris C.

doi:10.1101/2020.06.22.165621

Cited by 20 publications

(11 citation statements)

References 241 publications

(444 reference statements)

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“…Manifold learning techniques were utilized to compress and represent high dimensional functional connectomes along a series of spatial gradients. These approaches have recently seen an increasing adoption by the neuroimaging and network neuroscience communities (Burt et al, 2018;Demirtaş et al, 2019;Haak and Beckmann, 2020;Larivière et al, 2019bLarivière et al, , 2019aMüller et al, 2020;Paquola et al, , 2019bPark et al, 2020aPark et al, , 2020bVos de Wael et al, 2020;Vos De Wael et al, 2018) to interrogate macroscale neural organization and cortical hierarchy (Hong et al, 2019;Huntenburg et al, 2018;Margulies et al, 2016). Studying the HCP dataset, we identified three functional gradients explaining approximately 50% variance, in agreement with earlier studies in the same dataset (Margulies et al, 2016;Vos de Wael et al, 2020).…”

Section: Discussionsupporting

confidence: 87%

“…We simplified the multivariate manifolds into a single scalar value by calculating the Euclidean distance between the center of template manifold and all data points (i.e., brain regions) in the manifold space for each individual, which was referred to as manifold eccentricity ( Fig. 2A) (Bethlehem et al, 2020;Park et al, 2020b). We calculated linear correlation between BMI and the manifold eccentricity of the identified regions derived from the multivariate analysis (Fig.…”

Section: Macroscale Connectome Associated With Body Mass Indexmentioning

confidence: 99%

“…A hierarchical perspective is furthermore supported by work showing a close association between functional gradients and main axes of microstructural differentiation in the cortex, which concomitantly describe a sensory-fugal pattern (Huntenburg et al, 2017;Paquola et al, 2019aPaquola et al, , 2020. Connectome manifold learning has furthermore been applied to study healthy aging (Bethlehem et al, 2020;Lowe et al, 2019) and in the hierarchical organization of functional and structural networks in typical and atypical neurodevelopment (Hong et al, 2019;Paquola et al, 2019b;Park et al, 2020aPark et al, , 2020b. In the context of BMI, these techniques have still not been applied but could promise to identify whether different patterns of functional network integration and segregation underpin inter-individual body mass variations.…”

Section: Introductionmentioning

confidence: 99%

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Body mass variations relate to fractionated functional brain hierarchies

Park

Morys

et al. 2020

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Variations in body mass index (BMI) have been suggested to relate to atypical brain organization, yet connectome-level substrates of BMI and their neurobiological underpinnings remain unclear. Studying 325 healthy young adults, we examined association between functional connectome organization and BMI variations. We capitalized on connectome manifold learning techniques, which represent macroscale functional connectivity patterns along continuous hierarchical axes that dissociate low level and higher order brain systems. We observed an increased differentiation between unimodal and heteromodal association networks in individuals with higher BMI, indicative of an increasingly segregated modular architecture and a disruption in the hierarchical integration of different brain system. Transcriptomic decoding and subsequent gene enrichment analyses identified genes previously implicated in genome-wide associations to BMI and specific cortical, striatal, and cerebellar cell types. These findings provide novel insights for functional connectome substrates of BMI variations in healthy young adults and point to potential molecular associations.

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Section: Discussionsupporting

confidence: 87%

Section: Macroscale Connectome Associated With Body Mass Indexmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Body mass variations relate to fractionated functional brain hierarchies

Park

Morys

et al. 2020

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“…When we summarized the multivariate manifolds into a single scalar that represents manifold expansion and contraction 64,65 , we found evident contractions in somatomotor and posterior cingulate cortices, and expansions in heteromodal association cortex in individuals with autism relative to controls (Supplementary Fig. 1c), and these patterns were similar across both sites (Supplementary Fig.…”

Section: Resultsmentioning

confidence: 97%

“…Spatial association analysis between macroscale manifold distortions and postmortem gene expression maps from the Allen Institute for Brain Sciences (AIBS) pointed to potential neurobiological substrates of our manifold level findings. Recent studies in healthy brain organization 115,116 , development 39,65 , and disease 117,118 have shown how such analyses can help to understand the relationship between macroscopic neuroimaging phenotypes and spatial variations at the molecular scale 119 . In a prior study, similar approaches were used to identify genetic factors whose expression correlated to maps of cortical morphological variations in autism, and pointed to transcriptionally downregulated genes implicated in autism 120 .…”

Section: Discussionmentioning

confidence: 99%

Differences in subcortico-cortical interactions identified from connectome and microcircuit models in autism

et al. 2021

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The pathophysiology of autism has been suggested to involve a combination of both macroscale connectome miswiring and microcircuit anomalies. Here, we combine connectome-wide manifold learning with biophysical simulation models to understand associations between global network perturbations and microcircuit dysfunctions in autism. We studied neuroimaging and phenotypic data in 47 individuals with autism and 37 typically developing controls obtained from the Autism Brain Imaging Data Exchange initiative. Our analysis establishes significant differences in structural connectome organization in individuals with autism relative to controls, with strong between-group effects in low-level somatosensory regions and moderate effects in high-level association cortices. Computational models reveal that the degree of macroscale anomalies is related to atypical increases of recurrent excitation/inhibition, as well as subcortical inputs into cortical microcircuits, especially in sensory and motor areas. Transcriptomic association analysis based on postmortem datasets identifies genes expressed in cortical and thalamic areas from childhood to young adulthood. Finally, supervised machine learning finds that the macroscale perturbations are associated with symptom severity scores on the Autism Diagnostic Observation Schedule. Together, our analyses suggest that atypical subcortico-cortical interactions are associated with both microcircuit and macroscale connectome differences in autism.

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