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

Park, Bo‐yong; Hong, Seok‐Jun; Valk, Sofie L.; Paquola, Casey; Benkarim, Oualid; Bethlehem, Richard A. I.; Martino, Adriana Di; Milham, Michael P.; Gozzi, Alessandro; Yeo, B.T. Thomas; Smallwood, Jonathan; Bernhardt, Boris C.

doi:10.1038/s41467-021-21732-0

Cited by 76 publications

(67 citation statements)

References 175 publications

(308 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition to MRI-based analyses of regional morphology and microstructure, we performed a transcriptomic association analysis based on post-mortem gene expression maps provided by the Allen Brain Atlas. Although such transcriptomic associations were established through a different and small dataset that is not necessarily representative of the HCP sample, equivalent approaches have been increasingly adopted in neuroimaging research to identify genes whose expression patterns covary with macroscopic findings 45 , 50 , 62 – 66 . In our work, spatial association analyses pointed to specific gene sets, which were cross-referenced with previously reported genome-wide association studies.…”

Section: Discussionmentioning

confidence: 99%

“…The key to manifold learning is the ability to compress high-dimensional connectomes into a series of lower-dimensional eigenvectors (i.e., gradients) that visualize spatial trends in inter-regional connectivity variations 39 , simplifying connectivity analysis and visualization. Eigenvectors estimated from resting-state functional MRI (rs-fMRI), myelin-sensitive imaging, and diffusion MRI can serve as axes of the brain’s intrinsic coordinate system 39 – 45 . These eigenvectors have been shown to follow established models of neural hierarchy and laminar differentiation 46 .…”

Section: Introductionmentioning

confidence: 99%

“…Coupled with gene set enrichment analyses 57 – 61 , these approaches can discover molecular, developmental, and disease-related processes, and provide additional context for MRI findings. Recent studies utilized transcriptomic decoding to explore the underpinnings of brain imaging findings in both healthy and diseased cohorts 45 , 50 , 62 – 66 .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Inter-individual body mass variations relate to fractionated functional brain hierarchies

Park

Morys

et al. 2021

Commun Biol

Self Cite

View full text Add to dashboard Cite

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 associations between functional connectivity and inter-individual BMI variations. We utilized non-linear connectome manifold learning techniques to represent macroscale functional organization 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 a disrupted modular architecture and hierarchy of the brain. Transcriptomic decoding and gene enrichment analyses identified genes previously implicated in genome-wide associations to BMI and specific cortical, striatal, and cerebellar cell types. These findings illustrate functional connectome substrates of BMI variations in healthy young adults and point to potential molecular associations.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Inter-individual body mass variations relate to fractionated functional brain hierarchies

Park

Morys

et al. 2021

Commun Biol

Self Cite

View full text Add to dashboard Cite

show abstract

“…Machine learning is a powerful tool for analyzing neuroimaging data, and manifold learning techniques are increasingly being used to describe macroscale functional connectome organization along the cortex [27][28][29]52]. We generated a series of low-dimensional eigenvectors, and the spatial patterns agreed with those of existing studies based on the Human Connectome Project data [22,31,52].…”

Section: Discussionmentioning

confidence: 99%

Subgroups of Eating Behavior Traits Independent of Obesity Defined Using Functional Connectivity and Feature Representation Learning

Choi

Byeon

Lee

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

Eating behavior is highly heterogeneous across individuals, and thus, it cannot be fully explained using only the degree of obesity. We utilized unsupervised machine learning and functional connectivity measures to explore the heterogeneity of eating behaviors. This study was conducted on 424 healthy adults. We generated low-dimensional representations of functional connectivity defined using the resting-state functional magnetic resonance imaging, and calculated latent features using the feature representation capabilities of an autoencoder by nonlinearly compressing the functional connectivity information. The clustering approaches applied to latent features identified three distinct subgroups. The subgroups exhibited different disinhibition and hunger traits; however, their body mass indices were comparable. The model interpretation technique of integrated gradients revealed that these distinctions were associated with the functional reorganization in higher-order associations and limbic networks and reward-related subcortical structures. The cognitive decoding analysis revealed that these systems are associated with reward- and emotion-related systems. We replicated our findings using an independent dataset, thereby suggesting generalizability. Our findings provide insights into the macroscopic brain organization of eating behavior-related subgroups independent of obesity.

show abstract

“…It is controlled by two parameters α and t, where α controls the influence of the density of sampling points on the manifold (α = 0, maximal influence; α = 1, no influence) and t controls the scale of eigenvalues of the diffusion operator. We set α = 0.5 and t = 0 to retain the global relations between data points in the embedded space, following prior applications [17,20,28,41,46,98,99]. Cortical regions with more similar inter-regional patterns are more proximal in this new structural manifold.…”

Section: Structural Manifold Identificationmentioning

confidence: 99%

Adolescent development of multiscale structural wiring and functional interactions in the human connectome

Park

Paquola

Bethlehem

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Adolescence is a time of profound changes in the structural wiring of the brain and maturation of large-scale functional interactions. Here, we analyzed structural and functional brain network development in an accelerated longitudinal cohort spanning 14-25 years (n = 199). Core to our work was an advanced model of cortical wiring that incorporates multimodal MRI features of (i) cortico-cortical proximity, (ii) microstructural similarity, and (iii) diffusion tractography. Longitudinal analyses assessing age-related changes in cortical wiring during adolescence identified increases in cortical wiring within attention and default-mode networks, as well as between transmodal and attention, and sensory and limbic networks, indicative of a continued differentiation of cortico-cortical structural networks. Cortical wiring changes were statistically independent from age-related cortical thinning seen in the same subjects. Conversely, resting-state functional MRI analysis in the same subjects indicated an increasing segregation of sensory and transmodal systems during adolescence, with age-related reductions in their functional connectivity alongside with an increase in structural wiring distance. Our findings provide new insights into adolescent brain network development, illustrating how the maturation of structural wiring interacts with the development of macroscale network function.

show abstract

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

Cited by 76 publications

References 175 publications

Inter-individual body mass variations relate to fractionated functional brain hierarchies

Inter-individual body mass variations relate to fractionated functional brain hierarchies

Subgroups of Eating Behavior Traits Independent of Obesity Defined Using Functional Connectivity and Feature Representation Learning

Adolescent development of multiscale structural wiring and functional interactions in the human connectome

Contact Info

Product

Resources

About