Quantification of Structural Brain Connectivity via a Conductance Model

AbstaractConnectomics has proved promising in quantifying and understanding the effects of development, aging and an array of diseases on the brain. In this work, we propose a new structural connectivity measure from diffusion MRI that allows us to incorporate direct brain connections, as well as indirect ones that would not be otherwise accounted for by standard techniques and that may be key for the better understanding of function from structure. From our experiments on the Human Connectome Project dataset, we find that our measure of structural connectivity better correlates with functional connectivity than streamline tractography does, meaning that it provides new structural information related to function. Through additional experiments on the ADNI-2 dataset, we demonstrate the ability of this new measure to better discriminate different stages of Alzheimer’s disease. Our findings suggest that this measure is useful in the study of the normal brain structure, and for quantifying the effects of disease on the brain structure.

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Integrating multimodal connectivity improves prediction of individual cognitive abilities

10.1101/2020.06.25.172387 ◽

2020 ◽

Author(s):

Elvisha Dhamala ◽

Keith W. Jamison ◽

Abhishek Jaywant ◽

Sarah Dennis ◽

Amy Kuceyeski

Keyword(s):

Cognitive Abilities ◽

Structural Information ◽

Brain Connectivity ◽

Structural Connectivity ◽

Secondary Analysis ◽

Learning Approaches ◽

Activation Patterns ◽

Verbal Language ◽

Human Connectome Project ◽

Deterministic Tractography

SummaryHow white matter pathway integrity and neural co-activation patterns in the brain relate to complex cognitive functions remains a mystery in neuroscience. Here, we integrate neuroimaging, connectomics, and machine learning approaches to explore how multimodal brain connectivity relates to cognition. Specifically, we evaluate whether integrating functional and structural connectivity improves prediction of individual crystallised and fluid abilities in 415 unrelated healthy young adults from the Human Connectome Project. Our primary results are two-fold. First, we demonstrate that integrating functional and structural information – at both a model input or output level – significantly outperforms functional or structural connectivity alone to predict individual verbal/language skills and fluid reasoning/executive function. Second, we show that distinct pairwise functional and structural connections are important for these predictions. In a secondary analysis, we find that structural connectivity derived from deterministic tractography is significantly better than structural connectivity derived from probabilistic tractography to predict individual cognitive abilities.

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Determination of Dynamic Brain Connectivity via Spectral Analysis

Frontiers in Human Neuroscience ◽

10.3389/fnhum.2021.655576 ◽

2021 ◽

Vol 15 ◽

Author(s):

Peter A. Robinson ◽

James A. Henderson ◽

Natasha C. Gabay ◽

Kevin M. Aquino ◽

Tara Babaie-Janvier ◽

...

Keyword(s):

Spectral Analysis ◽

Brain Structure ◽

Brain Connectivity ◽

Spatial Scales ◽

Effective Connectivity ◽

Physical Nature ◽

Building Blocks ◽

Brain Dynamics ◽

Compact Representation ◽

The Brain

Spectral analysis based on neural field theory is used to analyze dynamic connectivity via methods based on the physical eigenmodes that are the building blocks of brain dynamics. These approaches integrate over space instead of averaging over time and thereby greatly reduce or remove the temporal averaging effects, windowing artifacts, and noise at fine spatial scales that have bedeviled the analysis of dynamical functional connectivity (FC). The dependences of FC on dynamics at various timescales, and on windowing, are clarified and the results are demonstrated on simple test cases, demonstrating how modes provide directly interpretable insights that can be related to brain structure and function. It is shown that FC is dynamic even when the brain structure and effective connectivity are fixed, and that the observed patterns of FC are dominated by relatively few eigenmodes. Common artifacts introduced by statistical analyses that do not incorporate the physical nature of the brain are discussed and it is shown that these are avoided by spectral analysis using eigenmodes. Unlike most published artificially discretized “resting state networks” and other statistically-derived patterns, eigenmodes overlap, with every mode extending across the whole brain and every region participating in every mode—just like the vibrations that give rise to notes of a musical instrument. Despite this, modes are independent and do not interact in the linear limit. It is argued that for many purposes the intrinsic limitations of covariance-based FC instead favor the alternative of tracking eigenmode coefficients vs. time, which provide a compact representation that is directly related to biophysical brain dynamics.

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Unique mapping of structural and functional connectivity on cognition

10.1101/296913 ◽

2018 ◽

Author(s):

J. Zimmermann ◽

J.G. Griffiths ◽

A.R. McIntosh

Keyword(s):

Functional Connectivity ◽

Brain Connectivity ◽

Structural Connectivity ◽

Brain Regions ◽

Unique Mapping ◽

Human Connectome Project ◽

Behavioural Patterns ◽

Wide Range ◽

Psychological Tasks ◽

New Evidence

AbstractThe unique mapping of structural and functional brain connectivity (SC, FC) on cognition is currently not well understood. It is not clear whether cognition is mapped via a global connectome pattern or instead is underpinned by several sets of distributed connectivity patterns. Moreover, we also do not know whether the pattern of SC and of FC that underlie cognition are overlapping or distinct. Here, we study the relationship between SC and FC and an array of psychological tasks in 609 subjects from the Human Connectome Project (HCP). We identified several sets of connections that each uniquely map onto different aspects of cognitive function. We found a small number of distributed SC and a larger set of cortico-cortical and cortico-subcortical FC that express this association. Importantly, SC and FC each show unique and distinct patterns of variance across subjects and differential relationships to cognition. The results suggest that a complete understanding of connectome underpinnings of cognition calls for a combination of the two modalities.Significance StatementStructural connectivity (SC), the physical white-matter inter-regional pathways in the brain, and functional connectivity (FC), the temporal co-activations between activity of brain regions, have each been studied extensively. Little is known, however, about the distribution of variance in connections as they relate to cognition. Here, in a large sample of subjects (N = 609), we showed that two sets of brain-behavioural patterns capture the correlations between SC, and FC with a wide range of cognitive tasks, respectively. These brain-behavioural patterns reveal distinct sets of connections within the SC and the FC network and provide new evidence that SC and FC each provide unique information for cognition.

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Differences in the major fiber-tracts of people with congenital and acquired blindness

Electronic Imaging ◽

10.2352/issn.2470-1173.2020.11.hvei-366 ◽

2020 ◽

Vol 2020 (11) ◽

pp. 366-1-366-7

Author(s):

Katherine E.M. Tregillus ◽

Lora T. Likova

Keyword(s):

Visual Loss ◽

Brain Connectivity ◽

Structural Connectivity ◽

Visual Deprivation ◽

Visual Development ◽

Superior Longitudinal Fasciculus ◽

Brain Images ◽

Fiber Tracts ◽

Congenitally Blind ◽

The Brain

In order to better understand how our visual system processes information, we must understand the underlying brain connectivity architecture, and how it can get reorganized under visual deprivation. The full extent to which visual development and visual loss affect connectivity is not well known. To investigate the effect of the onset of blindness on structural connectivity both at the whole-brain voxel-wise level and at the level of all major whitematter tracts, we applied two complementary Diffusion-Tension Imaging (DTI) methods, TBSS and AFQ. Diffusion-weighted brain images were collected from three groups of participants: congenitally blind (CB), acquired blind (AB), and fully sighted controls. The differences between these groups were evaluated on a voxel-wise scale with Tract-Based Spatial Statistics (TBSS) method, and on larger-scale with Automated Fiber Quantification (AFQ), a method that allows for between-group comparisons at the level of the major fiber tracts. TBSS revealed that both blind groups tended to have higher FA than sighted controls in the central structures of the brain. AFQ revealed that, where the three groups differed, congenitally blind participants tended to be more similar to sighted controls than to those participants who had acquired blindness later in life. These differences were specifically manifested in the left uncinated fasciculus, the right corticospinal fasciculus, and the left superior longitudinal fasciculus, areas broadly associated with a range of higher-level cognitive systems.

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Connectivity-Informed Adaptive Regularization for Generalized Outcomes

10.1101/322420 ◽

2018 ◽

Author(s):

Damian Brzyski ◽

Marta Karas ◽

Beau Ances ◽

Mario Dzemidzic ◽

Joaquin Goni ◽

...

Keyword(s):

Linear Regression ◽

Brain Connectivity ◽

Association Studies ◽

Structural Connectivity ◽

Laplacian Matrix ◽

External Information ◽

Penalty Term ◽

Generalized Linear Regression ◽

The Brain ◽

Structural Brain

AbstractOne of the challenging problems in the brain imaging research is a principled incorporation of information from different imaging modalities in association studies. Frequently, data from each modality is analyzed separately using, for instance, dimensionality reduction techniques, which result in a loss of mutual information. We propose a novel regularization method, griPEER (generalized ridgified Partially Empirical Eigenvectors for Regression) to estimate the association between the brain structure features and a scalar outcome within the generalized linear regression framework. griPEER provides a principled approach to use external information from the structural brain connectivity to improve the regression coefficient estimation. Our proposal incorporates a penalty term, derived from the structural connectivity Laplacian matrix, in the penalized generalized linear regression. We address both theoretical and computational issues and show that our method is robust to the incomplete information about the structural brain connectivity. We also provide a significance testing procedure for performing inference on the estimated coefficients in this model. griPEER is evaluated in extensive simulation studies and it is applied in classification of the HIV+ and HIV- individuals.

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A-GHN: Attention-based Fusion of Multiple GraphHeat Networks for Structural to Functional Brain Mapping

10.1101/2021.08.12.456134 ◽

2021 ◽

Author(s):

SUBBA REDDY OOTA ◽

Archi Yadav ◽

Arpita Dash ◽

Surampudi Bapi Raju ◽

Avinash Sharma

Keyword(s):

Deep Learning ◽

Functional Connectivity ◽

Complex Dynamics ◽

Brain Activity ◽

Structural Connectivity ◽

Reaction Diffusion ◽

Complex Nature ◽

Relational Structures ◽

Human Connectome Project ◽

The Brain

Over the last decade, there has been growing interest in learning the mapping from structural connectivity (SC) to functional connectivity (FC) of the brain. The spontaneous fluctuations of the brain activity during the resting-state as captured by functional MRI (rsfMRI) contain rich non-stationary dynamics over a relatively fixed structural connectome. Among the modeling approaches, graph diffusion-based methods with single and multiple diffusion kernels approximating static or dynamic functional connectivity have shown promise in predicting the FC given the SC. However, these methods are computationally expensive, not scalable, and fail to capture the complex dynamics underlying the whole process. Recently, deep learning methods such as GraphHeat networks along with graph diffusion have been shown to handle complex relational structures while preserving global information. In this paper, we propose a novel attention-based fusion of multiple GraphHeat networks (A-GHN) for mapping SC-FC. A-GHN enables us to model multiple heat kernel diffusion over the brain graph for approximating the complex Reaction Diffusion phenomenon. We argue that the proposed deep learning method overcomes the scalability and computational inefficiency issues but can still learn the SC-FC mapping successfully. Training and testing were done using the rsfMRI data of 100 participants from the human connectome project (HCP), and the results establish the viability of the proposed model. Furthermore, experiments demonstrate that A-GHN outperforms the existing methods in learning the complex nature of human brain function.

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Structurally constrained effective brain connectivity

10.31219/osf.io/4erqd ◽

2021 ◽

Author(s):

Alessandro Crimi

Keyword(s):

Community Detection ◽

Autoregressive Model ◽

Brain Connectivity ◽

Effective Connectivity ◽

Structural Connectivity ◽

Ground Truth ◽

Autism Spectrum ◽

Case Control ◽

Functional Dependencies ◽

The Brain

The relationship between structure and function is of interest in many research fields involving the study of complex biological processes. In neuroscience in particular, the fusion of structural and functional data can help to understand the underlying principles of the operational networks in the brain. To address this issue, this paper proposes a constrained autoregressive model leading to a representation of effective connectivity that can be used to better understand how the structure modulates the function. Or simply, it can be used to find novel biomarkers characterizing groups of subjects. In practice, an initial structural connectivity representation is re-weighted to explain the functional co-activations. This is obtained by minimizing the reconstruction error of an autoregressive model constrained by the structural connectivity prior. The model has been designed to also include indirect connections, allowing to split direct and indirect components in the functional connectivity, and it can be used with raw and deconvoluted BOLD signal.The derived representation of dependencies was compared to the well known dynamic causal model, giving results closer to known ground-truth. Further evaluation of the proposed effective network was performed on two typical tasks. In a first experiment the direct functional dependencies were tested on a community detection problem, where the brain was partitioned using the effective networks across multiple subjects. In a second experiment the model was validated in a case-control task, which aimed at differentiating healthy subjects from individuals with autism spectrum disorder. Results showed that using effective connectivity leads to clusters better describing the functional interactions in the community detection task, while maintaining the original structural organization, and obtaining a better discrimination in the case-control classification task.

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A functional-structural connectivity metric detects ipsilateral connections with distinct functional specialisation in each hemisphere

10.1101/2020.12.03.410902 ◽

2020 ◽

Author(s):

Oren Civier ◽

Marion Sourty ◽

Fernando Calamante

Keyword(s):

Functional Connectivity ◽

Functional Mri ◽

Measurement Errors ◽

Diffusion Mri ◽

Right Hemisphere ◽

Structural Connectivity ◽

Joint Analysis ◽

Fibre Bundles ◽

Human Connectome Project ◽

The Brain

AbstractWe introduce a connectomics metric that integrates information on structural connectivity (SC) from diffusion MRI tractography and functional connectivity (FC) from resting-state functional MRI, at individual subject level. The metric is based on the ability of SC to broadly predict FC using a simple linear predictive model; for each connection in the brain, the metric quantifies the deviation from that model. For the metric to capture underlying physiological properties, we minimise systematic measurement errors and processing biases in both SC and FC, and address several challenges with the joint analysis. This also includes a data-driven normalisation approach. The combined metric may provide new information by indirectly assessing white matter structural properties that cannot be inferred from diffusion MRI alone, and/or complex interregional neural interactions that cannot be inferred from functional MRI alone. To demonstrate the utility of the metric, we used young adult data from the Human Connectome Project to examine all bilateral pairs of ipsilateral connections, i.e. each left-hemisphere connection in the brain was paired with its right-hemisphere homologue. We detected a minority of bilateral pairs where the metric value is significantly different across hemispheres, which we suggest reflects cases of ipsilateral connections that have distinct functional specialisation in each hemisphere. The pairs with significant effects spanned all cortical lobes, and also included several cortico-subcortical connections. Our findings highlight the potential in a joint analysis of structural and functional measures of connectivity, both for clinical applications and to help in the interpretation of results from standard functional connectivity analysis.Significance StatementBased on the notion that structure predicts function, the scientific community sought to demonstrate that structural information on fibre bundles that connect brain regions is sufficient to estimate the strength of interregional interactions. However, an accurate prediction using MRI has proved elusive. This paper posits that the failure to predict function from structure originates from limitations in measurement or interpretation of either diffusion MRI (to assess fibre bundles), fMRI (to assess functional interactions), or both. We show that these limitations can be nevertheless beneficial, as the extent of divergence between the two modalities may reflect hard-to-measure properties of interregional connections, such as their functional role in the brain. This provides many insights, including into the division of labour between hemispheres.

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Using Diffusion Tensor Imaging to examine brain structural plasticity and language experience

10.31234/osf.io/468xa ◽

2019 ◽

Author(s):

Gigi Luk ◽

Christos Pliatsikas

Keyword(s):

Language Processing ◽

Brain Structure ◽

Language Use ◽

Diffusion Tensor ◽

Brain Plasticity ◽

Structural Connectivity ◽

Brain Regions ◽

Language Experience ◽

Brain Correlates ◽

The Brain

Recent advances in neuroimaging methods have led to a renewed interest in the brain correlates of language processing. Most intriguing is how experiences of language use relates to variation in brain structure and how brain structure predicts language acquisition. These two lines of inquiry have important implications on considering language use as an experience-dependent mechanism that induces brain plasticity. This paper focuses on the structural connectivity of the brain, as delivered by white matter, i.e. the collections of the axons of the brain neurons that provide connectivity between brain regions. Tract-Based Spatial Statistics (TBSS), a method commonly used in the field, will be presented in detail. Readers will be introduced to procedures for the extraction of indices of variation in WM structure such as fractional anisotropy. Furthermore, the role of individual differences in WM and changes in WM pertaining to bilingual experience and language processing will be used as examples to illustrate the applicability of this method.

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Timescales of spontaneous fMRI fluctuations relate to structural connectivity in the brain

10.1101/655050 ◽

2019 ◽

Cited By ~ 3

Author(s):

John Fallon ◽

Phil Ward ◽

Linden Parkes ◽

Stuart Oldham ◽

Aurina Arnatkevic̆iūtė ◽

...

Keyword(s):

Resting State ◽

Structural Connectivity ◽

Resting State Fmri ◽

Information Storage ◽

Brain Organization ◽

Temporal Properties ◽

Temporal Features ◽

Human Connectome Project ◽

The Brain ◽

Connectivity Strength

AbstractIntrinsic timescales of activity fluctuations vary hierarchically across the brain. This variation reflects a broad gradient of functional specialization in information storage and processing, with integrative association areas displaying slower timescales that are thought to reflect longer temporal processing windows. The organization of timescales is associated with cognitive function, distinctive between individuals, and disrupted in disease, but we do not yet understand how the temporal properties of activity dynamics are shaped by the brain’s underlying structural-connectivity network. Using resting-state fMRI and diffusion MRI data from 100 healthy individuals from the Human Connectome Project, here we show that the timescale of resting-state fMRI dynamics increases with structural-connectivity strength, matching recent results in the mouse brain. Our results hold at the level of individuals, are robust to parcellation schemes, and are conserved across a range of different timescale-related statistics. We establish a comprehensive BOLD dynamical signature of structural connectivity strength by comparing over 6000 time-series features, highlighting a range of new temporal features for characterizing BOLD dynamics, including measures of stationarity and symbolic motif frequencies. Our findings indicate a conserved property of mouse and human brain organization in which a brain region’s spontaneous activity fluctuations are closely related to their surrounding structural scaffold.

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