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2. Modeling observed gender imbalances in academic citation practices

Author

Stiso, Jennifer, Oudyk, Kendra, Bertolero, Maxwell M., Zhou, Dale, Teich, Erin G., Lydon-Staley, David M., Zurn, Perry, and Bassett, Dani S.

Subjects
Computer Science - Digital Libraries, Quantitative Biology - Neurons and Cognition
Abstract

In multiple academic disciplines, having a perceived gender of `woman' is associated with a lower than expected rate of citations. In some fields, that disparity is driven primarily by the citations of men and is increasing over time despite increasing diversification of the profession. It is likely that complex social interactions and individual ideologies shape these disparities. Computational models of select factors that reproduce empirical observations can help us understand some of the minimal driving forces behind these complex phenomena and therefore aid in their mitigation. Here, we present a simple agent-based model of citation practices within academia, in which academics generate citations based on three factors: their estimate of the collaborative network of the field, how they sample that estimate, and how open they are to learning about their field from other academics. We show that increasing homophily -- or the tendency of people to interact with others more like themselves -- in these three domains is sufficient to reproduce observed biases in citation practices. We find that homophily in sampling an estimate of the field influences total citation rates, and openness to learning from new and unfamiliar authors influences the change in those citations over time. We next model a real-world intervention -- the citation diversity statement -- which has the potential to influence both of these parameters. We determine a parameterization of our model that matches the citation practices of academics who use the citation diversity statement. This parameterization paired with an openness to learning from many new authors can result in citation practices that are equitable and stable over time. Ultimately, our work underscores the importance of homophily in shaping citation practices and provides evidence that specific actions may mitigate biased citation practices in academia.

Published
2022

5. The information content of brain states is explained by structural constraints on state energetics

Author

Weninger, Leon, Srivastava, Pragya, Zhou, Dale, Kim, Jason Z., Cornblath, Eli J., Bertolero, Maxwell A., Habel, Ute, Merhof, Dorit, and Bassett, Dani S.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics, 93-08 (primary), 92-08, 94-05 (secondary), G.3, H.1.1, J.3
Abstract

Signal propagation along the structural connectome of the brain induces changes in the patterns of activity. These activity patterns define global brain states and contain information in accordance with their expected probability of occurrence. The structural connectome, in conjunction with the dynamics, determines the set of possible brain states and constrains the transition between accessible states. Yet, precisely how these structural constraints on state-transitions relate to their information content remains unexplored. To address this gap in knowledge, we defined the information content as a function of the activation distribution, where statistically rare values of activation correspond to high information content. With this numerical definition in hand, we studied the spatiotemporal distribution of information content in fMRI data from the Human Connectome Project during different tasks, and report four key findings. First, information content strongly depends on the cognitive task. Second, while information content shows similarities to other measures of brain activity, it is distinct from both Neurosynth maps and task contrast maps generated by a general linear model applied to the fMRI data. Third, the brain's structural wiring constrains the cost to control its state, where the cost to transition into high information content states is larger than that to transition into low information content states. Finally, all state transitions - especially those to high information content states - are less costly than expected from random network null models, thereby indicating the brain's marked efficiency. Taken together, our findings establish an explanatory link between the information contained in a brain state and the energetic cost of attaining that state, thereby laying important groundwork for our understanding of large-scale cognitive computations., Comment: 16 pages, 4 figures + supplement (5 pages, 5 figures)

Published
2021
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7. ASLPrep: a platform for processing of arterial spin labeled MRI and quantification of regional brain perfusion

Author

Adebimpe, Azeez, Bertolero, Maxwell, Dolui, Sudipto, Cieslak, Matthew, Murtha, Kristin, Baller, Erica B, Boeve, Bradley, Boxer, Adam, Butler, Ellyn R, Cook, Phil, Colcombe, Stan, Covitz, Sydney, Davatzikos, Christos, Davila, Diego G, Elliott, Mark A, Flounders, Matthew W, Franco, Alexandre R, Gur, Raquel E, Gur, Ruben C, Jaber, Basma, McMillian, Corey, Milham, Michael, Mutsaerts, Henk JMM, Oathes, Desmond J, Olm, Christopher A, Phillips, Jeffrey S, Tackett, Will, Roalf, David R, Rosen, Howard, Tapera, Tinashe M, Tisdall, M Dylan, Zhou, Dale, Esteban, Oscar, Poldrack, Russell A, Detre, John A, and Satterthwaite, Theodore D

Subjects
Biological Sciences, Clinical Research, Bioengineering, Brain Disorders, Neurosciences, Biomedical Imaging, Brain, Cerebrovascular Circulation, Humans, Magnetic Resonance Imaging, Perfusion, Spin Labels, ALLFTD Consortium, Technology, Medical and Health Sciences, Developmental Biology, Biological sciences
Abstract

Arterial spin labeled (ASL) magnetic resonance imaging (MRI) is the primary method for noninvasively measuring regional brain perfusion in humans. We introduce ASLPrep, a suite of software pipelines that ensure the reproducible and generalizable processing of ASL MRI data.

Published
2022

8. Personalized functional brain network topography is associated with individual differences in youth cognition

Author

Arielle S. Keller, Adam R. Pines, Sheila Shanmugan, Valerie J. Sydnor, Zaixu Cui, Maxwell A. Bertolero, Ran Barzilay, Aaron F. Alexander-Bloch, Nora Byington, Andrew Chen, Gregory M. Conan, Christos Davatzikos, Eric Feczko, Timothy J. Hendrickson, Audrey Houghton, Bart Larsen, Hongming Li, Oscar Miranda-Dominguez, David R. Roalf, Anders Perrone, Alisha Shetty, Russell T. Shinohara, Yong Fan, Damien A. Fair, and Theodore D. Satterthwaite

Subjects
Science
Abstract

Abstract Individual differences in cognition during childhood are associated with important social, physical, and mental health outcomes in adolescence and adulthood. Given that cortical surface arealization during development reflects the brain’s functional prioritization, quantifying variation in the topography of functional brain networks across the developing cortex may provide insight regarding individual differences in cognition. We test this idea by defining personalized functional networks (PFNs) that account for interindividual heterogeneity in functional brain network topography in 9–10 year olds from the Adolescent Brain Cognitive Development℠ Study. Across matched discovery (n = 3525) and replication (n = 3447) samples, the total cortical representation of fronto-parietal PFNs positively correlates with general cognition. Cross-validated ridge regressions trained on PFN topography predict cognition in unseen data across domains, with prediction accuracy increasing along the cortex’s sensorimotor-association organizational axis. These results establish that functional network topography heterogeneity is associated with individual differences in cognition before the critical transition into adolescence.

Published
2023
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10. Is the brain macroscopically linear? A system identification of resting state dynamics

Author

Nozari, Erfan, Bertolero, Maxwell A., Stiso, Jennifer, Caciagli, Lorenzo, Cornblath, Eli J., He, Xiaosong, Mahadevan, Arun S., Pappas, George J., and Bassett, Dani Smith

Subjects
Quantitative Biology - Neurons and Cognition, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing, Mathematics - Dynamical Systems, Mathematics - Optimization and Control
Abstract

A central challenge in the computational modeling of neural dynamics is the trade-off between accuracy and simplicity. At the level of individual neurons, nonlinear dynamics are both experimentally established and essential for neuronal functioning. An implicit assumption has thus formed that an accurate computational model of whole-brain dynamics must also be highly nonlinear, whereas linear models may provide a first-order approximation. Here, we provide a rigorous and data-driven investigation of this hypothesis at the level of whole-brain blood-oxygen-level-dependent (BOLD) and macroscopic field potential dynamics by leveraging the theory of system identification. Using functional MRI (fMRI) and intracranial EEG (iEEG), we model the resting state activity of 700 subjects in the Human Connectome Project (HCP) and 122 subjects from the Restoring Active Memory (RAM) project using state-of-the-art linear and nonlinear model families. We assess relative model fit using predictive power, computational complexity, and the extent of residual dynamics unexplained by the model. Contrary to our expectations, linear auto-regressive models achieve the best measures across all three metrics, eliminating the trade-off between accuracy and simplicity. To understand and explain this linearity, we highlight four properties of macroscopic neurodynamics which can counteract or mask microscopic nonlinear dynamics: averaging over space, averaging over time, observation noise, and limited data samples. Whereas the latter two are technological limitations and can improve in the future, the former two are inherent to aggregated macroscopic brain activity. Our results, together with the unparalleled interpretability of linear models, can greatly facilitate our understanding of macroscopic neural dynamics and the principled design of model-based interventions for the treatment of neuropsychiatric disorders.

Published
2020

11. Broken detailed balance and entropy production in the human brain

Author

Lynn, Christopher W., Cornblath, Eli J., Papadopoulos, Lia, Bertolero, Maxwell A., and Bassett, Danielle S.

Subjects
Physics - Biological Physics, Condensed Matter - Statistical Mechanics, Quantitative Biology - Neurons and Cognition
Abstract

Living systems break detailed balance at small scales, consuming energy and producing entropy in the environment in order to perform molecular and cellular functions. However, it remains unclear how broken detailed balance manifests at macroscopic scales, and how such dynamics support higher-order biological functions. Here we present a framework to quantify broken detailed balance by measuring entropy production in macroscopic systems. We apply our method to the human brain, an organ whose immense metabolic consumption drives a diverse range of cognitive functions. Using whole-brain imaging data, we demonstrate that the brain nearly obeys detailed balance when at rest, but strongly breaks detailed balance when performing physically and cognitively demanding tasks. Using a dynamic Ising model, we show that these large-scale violations of detailed balance can emerge from fine-scale asymmetries in the interactions between elements, a known feature of neural systems. Together, these results suggest that violations of detailed balance are vital for cognition, and provide a general tool for quantifying entropy production in macroscopic systems., Comment: 19 pages, 15 figures

Published
2020
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12. Deep Neural Networks Carve the Brain at its Joints

Author

Bertolero, Maxwell A., Moraczewski, Dustin, Thomas, Adam, and Bassett, Danielle S.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Data Analysis, Statistics and Probability, Quantitative Biology - Quantitative Methods
Abstract

How an individual's unique brain connectivity determines that individual's cognition, behavior, and risk for pathology is a fundamental question in basic and clinical neuroscience. In seeking answers, many have turned to machine learning, with some noting the particular promise of deep neural networks in modelling complex non-linear functions. However, it is not clear that complex functions actually exist between brain connectivity and behavior, and thus if deep neural networks necessarily outperform simpler linear models, or if their results would be interpretable. Here we show that, across 52 subject measures of cognition and behavior, deep neural networks fit to each brain region's connectivity outperform linear regression, particularly for the brain's connector hubs--regions with diverse brain connectivity--whereas the two approaches perform similarly when fit to brain systems. Critically, averaging deep neural network predictions across brain regions results in the most accurate predictions, demonstrating the ability of deep neural networks to easily model the various functions that exists between regional brain connectivity and behavior, carving the brain at its joints. Finally, we shine light into the black box of deep neural networks using multislice network models. We determined that the relationship between connector hubs and behavior is best captured by modular deep neural networks. Our results demonstrate that both simple and complex relationships exist between brain connectivity and behavior, and that deep neural networks can fit both. Moreover, deep neural networks are particularly powerful when they are first fit to the various functions of a system independently and then combined. Finally, deep neural networks are interpretable when their architectures are structurally characterized using multislice network models.

Published
2020

13. Personalized functional brain network topography is associated with individual differences in youth cognition

Author

Keller, Arielle S., Pines, Adam R., Shanmugan, Sheila, Sydnor, Valerie J., Cui, Zaixu, Bertolero, Maxwell A., Barzilay, Ran, Alexander-Bloch, Aaron F., Byington, Nora, Chen, Andrew, Conan, Gregory M., Davatzikos, Christos, Feczko, Eric, Hendrickson, Timothy J., Houghton, Audrey, Larsen, Bart, Li, Hongming, Miranda-Dominguez, Oscar, Roalf, David R., Perrone, Anders, Shetty, Alisha, Shinohara, Russell T., Fan, Yong, Fair, Damien A., and Satterthwaite, Theodore D.

Published
2023
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14. Development of white matter fiber covariance networks supports executive function in youth

Author

Bagautdinova, Joëlle, Bourque, Josiane, Sydnor, Valerie J., Cieslak, Matthew, Alexander-Bloch, Aaron F., Bertolero, Maxwell A., Cook, Philip A., Gur, Raquel E., Gur, Ruben C., Hu, Fengling, Larsen, Bart, Moore, Tyler M., Radhakrishnan, Hamsanandini, Roalf, David R., Shinohara, Russel T., Tapera, Tinashe M., Zhao, Chenying, Sotiras, Aristeidis, Davatzikos, Christos, and Satterthwaite, Theodore D.

Published
2023
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15. Development of white matter fiber covariance networks supports executive function in youth

Author

Joëlle Bagautdinova, Josiane Bourque, Valerie J. Sydnor, Matthew Cieslak, Aaron F. Alexander-Bloch, Maxwell A. Bertolero, Philip A. Cook, Raquel E. Gur, Ruben C. Gur, Fengling Hu, Bart Larsen, Tyler M. Moore, Hamsanandini Radhakrishnan, David R. Roalf, Russel T. Shinohara, Tinashe M. Tapera, Chenying Zhao, Aristeidis Sotiras, Christos Davatzikos, and Theodore D. Satterthwaite

Subjects
CP: Neuroscience, Biology (General), QH301-705.5
Abstract

Summary: During adolescence, the brain undergoes extensive changes in white matter structure that support cognition. Data-driven approaches applied to cortical surface properties have led the field to understand brain development as a spatially and temporally coordinated mechanism that follows hierarchically organized gradients of change. Although white matter development also appears asynchronous, previous studies have relied largely on anatomical tract-based atlases, precluding a direct assessment of how white matter structure is spatially and temporally coordinated. Harnessing advances in diffusion modeling and machine learning, we identified 14 data-driven patterns of covarying white matter structure in a large sample of youth. Fiber covariance networks aligned with known major tracts, while also capturing distinct patterns of spatial covariance across distributed white matter locations. Most networks showed age-related increases in fiber network properties, which were also related to developmental changes in executive function. This study delineates data-driven patterns of white matter development that support cognition.

Published
2023
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16. On the nature of explanations offered by network science: A perspective from and for practicing neuroscientists

Author

Bertolero, Maxwell A. and Bassett, Danielle S.

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Network neuroscience represents the brain as a collection of regions and inter-regional connections. Given its ability to formalize systems-level models, network neuroscience has generated unique explanations of neural function and behavior. The mechanistic status of these explanations and how they can contribute to and fit within the field of neuroscience as a whole has received careful treatment from philosophers. However, these philosophical contributions have not yet reached many neuroscientists. Here we complement formal philosophical efforts by providing an applied perspective from and for neuroscientists. We discuss the mechanistic status of the explanations offered by network neuroscience and how they contribute to, enhance, and interdigitate with other types of explanations in neuroscience. In doing so, we rely on philosophical work concerning the role of causality, scale, and mechanisms in scientific explanations. In particular, we make the distinction between an explanation and the evidence supporting that explanation, and we argue for a scale-free nature of mechanistic explanations. In the course of these discussions, we hope to provide a useful applied framework in which network neuroscience explanations can be exercised across scales and combined with other fields of neuroscience to gain deeper insights into the brain and behavior., Comment: This article is part a forthcoming Topics in Cognitive Science Special Issue: "Levels of Explanation in Cognitive Science: From Molecules to Culture," Matteo Colombo and Markus Knauff (Topic Editors)

Published
2019

18. The human brain's network architecture is genetically encoded by modular pleiotropy

Author

Bertolero, Maxwell A., Blevins, Ann Sizemore, Baum, Graham L., Gur, Ruben C., Gur, Raquel E., Roalf, David R., Satterthwaite, Theodore D., and Bassett, Danielle S.

Subjects
Quantitative Biology - Neurons and Cognition, Quantitative Biology - Genomics, Quantitative Biology - Populations and Evolution
Abstract

For much of biology, the manner in which genotype maps to phenotype remains a fundamental mystery. The few maps that are known tend to show modular pleiotropy: sets of phenotypes are determined by distinct sets of genes. One key map that has evaded discovery is that of the human brain's network architecture. Here, we determine the form of this map for gene coexpression and single nucleotide polymorphisms. We discover that mostly non-overlapping sets of genes encode the connectivity of brain network modules (or so-called communities), suggesting that brain network communities demarcate genetic transitions. We find that these clean boundaries break down at connector hubs, whose integrative connectivity is encoded by pleiotropic genes from mostly non-overlapping sets. Broadly, this study opens fundamentally new directions in the study of genetic encoding of brain development, evolution, and disease.

Published
2019

19. Multiscale and multimodal network dynamics underpinning working memory

Author

Murphy, Andrew C., Bertolero, Maxwell A., Papadopoulos, Lia, Lydon-Staley, David M., and Bassett, Danielle S.

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Working memory (WM) allows information to be stored and manipulated over short time scales. Performance on WM tasks is thought to be supported by the frontoparietal system (FPS), the default mode system (DMS), and interactions between them. Yet little is known about how these systems and their interactions relate to individual differences in WM performance. We address this gap in knowledge using functional MRI data acquired during the performance of a 2-back WM task, as well as diffusion tensor imaging data collected in the same individuals. We show that the strength of functional interactions between the FPS and DMS during task engagement is inversely correlated with WM performance, and that this strength is modulated by the activation of FPS regions but not DMS regions. Next, we use a clustering algorithm to identify two distinct subnetworks of the FPS, and find that these subnetworks display distinguishable patterns of gene expression. Activity in one subnetwork is positively associated with the strength of FPS-DMS functional interactions, while activity in the second subnetwork is negatively associated. Further, the pattern of structural linkages of these subnetworks explains their differential capacity to influence the strength of FPS-DMS functional interactions. To determine whether these observations could provide a mechanistic account of large-scale neural underpinnings of WM, we build a computational model of the system composed of coupled oscillators. Modulating the amplitude of the subnetworks in the model causes the expected change in the strength of FPS-DMS functional interactions, thereby offering support for a mechanism in which subnetwork activity tunes functional interactions. Broadly, our study presents a holistic account of how regional activity, functional interactions, and structural linkages together support individual differences in WM in humans.

Published
2019
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20. Development of top-down cortical propagations in youth

Author

Pines, Adam, Keller, Arielle S., Larsen, Bart, Bertolero, Maxwell, Ashourvan, Arian, Bassett, Dani S., Cieslak, Matthew, Covitz, Sydney, Fan, Yong, Feczko, Eric, Houghton, Audrey, Rueter, Amanda R., Saggar, Manish, Shafiei, Golia, Tapera, Tinashe M., Vogel, Jacob, Weinstein, Sarah M., Shinohara, Russell T., Williams, Leanne M., Fair, Damien A., and Satterthwaite, Theodore D.

Published
2023
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24. Drivers of resource allocation for breeding under variable environments in a bet hedger

Author

Daniel Oro, Cassidy Waldrep, Albert Bertolero, and Meritxell Genovart

Subjects
age, bet‐hedging, clutch size, food, intra‐clutch asymmetries, long‐lived bird, Ecology, QH540-549.5
Abstract

Abstract The evolutionary theory of life histories predicts that there is a trade‐off between survival and reproduction: since adult survival in long‐lived organisms is high, then breeding investment is more variable and more dependent on conditions (e.g. food availability and individual experience). Clutch features influence fitness prospects, but how a bet hedger builds its clutch in temporally varying environments is quite unknown. Using 27‐year data on 2847 clutches of known‐age breeders, we analyse how Audouin's gulls (Larus audouinii), a species showing a combination of conservative and adaptive bet‐hedging breeding strategies, can allocate energy by laying clutches and eggs of different sizes. Results show that both food availability and age influenced clutch size and total egg volume in a clutch. Interestingly, we found an interaction between food and age on egg parameters: total volume in two‐egg clutches, laid mostly by younger breeders, did not significantly change with food availability and the quadratic pattern in clutch size over the range of ages was less marked as long as food conditions became harsher. With increased food, females invested more by building larger first eggs, whereas they were more conservative on second and third eggs. Furthermore, asymmetries in egg volume within three‐egg clutches increased with food availability for old females. Egg size profiles of two‐egg clutches suggest that gulls should exhibit progressive reduction of the size of the third egg before shifting to a two‐egg clutch size. Food availability influenced all parameters studied, whereas age affected the amount of energy allocated for producing eggs (their size and number) but not the way of allocating those energies (i.e. asymmetries within the clutch). Despite the range of factors affecting the clutch, results suggest that females can allocate the amount of resources in a clutch optimally to increase their fitness under variable environments via bet‐hedging.

Published
2023
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25. Learning differentially reorganizes brain activity and connectivity

Author

Bertolero, Maxwell A, Adebimpe, Azeez, Khambhati, Ankit N., Mattar, Marcelo G., Romer, Daniel, Thompson-Schill, Sharon L., and Bassett, Danielle S.

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Human learning is a complex process in which future behavior is altered via the reorganization of brain activity and connectivity. It remains unknown whether activity and connectivity differentially reorganize during learning, and, if so, how that differential reorganization tracks stages of learning across distinct brain areas. Here, we address this gap in knowledge by measuring brain activity and functional connectivity in a longitudinal fMRI experiment in which healthy adult human participants learn the values of novel objects over the course of four days. An increasing similarity in activity or functional connectivity across subjects during learning reflects reorganization toward a common functional architecture. We assessed the presence of reorganization in activity and connectivity both during value learning and during the resting-state, allowing us to differentiate common elicited processes from intrinsic processes. We found a complex and dynamic reorganization of brain connectivity and activity--as a function of time, space, and performance--that occurs while subjects learn. Spatially localized brain activity reorganizes across the brain to a common functional architecture early in learning, and this reorganization tracks early learning performance. In contrast, spatially distributed connectivity reorganizes across the brain to a common functional architecture as training progresses, and this reorganization tracks later learning performance. Particularly good performance is associated with a sticky connectivity, that persists into the resting state. Broadly, our work uncovers distinct principles of reorganization in activity and connectivity at different phases of value learning, which inform the ongoing study of learning processes more generally.

Published
2018

26. A mechanistic model of connector hubs, modularity, and cognition

Author

Bertolero, Maxwell A., Yeo, B. T. T., Bassett, Danielle S., and D'Esposito, Mark

Subjects
Quantitative Biology - Neurons and Cognition, Quantitative Biology - Quantitative Methods
Abstract

The human brain network is modular--comprised of communities of tightly interconnected nodes. This network contains local hubs, which have many connections within their own communities, and connector hubs, which have connections diversely distributed across communities. A mechanistic understanding of these hubs and how they support cognition has not been demonstrated. Here, we leveraged individual differences in hub connectivity and cognition. We show that a model of hub connectivity accurately predicts the cognitive performance of 476 individuals in four distinct tasks. Moreover, there is a general optimal network structure for cognitive performance--individuals with diversely connected hubs and consequent modular brain networks exhibit increased cognitive performance, regardless of the task. Critically, we find evidence consistent with a mechanistic model in which connector hubs tune the connectivity of their neighbors to be more modular while allowing for task appropriate information integration across communities, which increases global modularity and cognitive performance.

Published
2018
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27. Inferring the age of breeders from easily measurable variables

Author

Meritxell Genovart, Katarina Klementisová, Daniel Oro, Pol Fernández-López, Albert Bertolero, and Frederic Bartumeus

Subjects
Medicine, Science
Abstract

Abstract Age drives differences in fitness components typically due to lower performances of younger and senescent individuals, and changes in breeding age structure influence population dynamics and persistence. However, determining age and age structure is challenging in most species, where distinctive age features are lacking and available methods require substantial efforts or invasive procedures. Here we explore the potential to assess the age of breeders, or at least to identify young and senescent individuals, by measuring some breeding parameters partially driven by age (e.g. egg volume in birds). Taking advantage of a long-term population monitored seabird, we first assessed whether age influenced egg volume, and identified other factors driving this trait by using general linear models. Secondly, we developed and evaluated a machine learning algorithm to assess the age of breeders using measurable variables. We confirmed that both younger and older individuals performed worse (less and smaller eggs) than middle-aged individuals. Our ensemble training algorithm was only able to distinguish young individuals, but not senescent breeders. We propose to test the combined use of field monitoring, classic regression analysis and machine learning methods in other wild populations were measurable breeding parameters are partially driven by age, as a possible tool for assessing age structure in the wild.

Published
2022
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28. Linking Individual Differences in Personalized Functional Network Topography to Psychopathology in Youth

Author

Cui, Zaixu, Pines, Adam R., Larsen, Bart, Sydnor, Valerie J., Li, Hongming, Adebimpe, Azeez, Alexander-Bloch, Aaron F., Bassett, Dani S., Bertolero, Max, Calkins, Monica E., Davatzikos, Christos, Fair, Damien A., Gur, Ruben C., Gur, Raquel E., Moore, Tyler M., Shanmugan, Sheila, Shinohara, Russell T., Vogel, Jacob W., Xia, Cedric H., Fan, Yong, and Satterthwaite, Theodore D.

Published
2022
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29. Curation of BIDS (CuBIDS): A workflow and software package for streamlining reproducible curation of large BIDS datasets

Author

Covitz, Sydney, Tapera, Tinashe M., Adebimpe, Azeez, Alexander-Bloch, Aaron F., Bertolero, Maxwell A., Feczko, Eric, Franco, Alexandre R., Gur, Raquel E., Gur, Ruben C., Hendrickson, Timothy, Houghton, Audrey, Mehta, Kahini, Murtha, Kristin, Perrone, Anders J., Robert-Fitzgerald, Tim, Schabdach, Jenna M., Shinohara, Russell T, Vogel, Jacob W., Zhao, Chenying, Fair, Damien A., Milham, Michael P., Cieslak, Matthew, and Satterthwaite, Theodore D.

Published
2022
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31. Dissociable multi-scale patterns of development in personalized brain networks

Author

Adam R. Pines, Bart Larsen, Zaixu Cui, Valerie J. Sydnor, Maxwell A. Bertolero, Azeez Adebimpe, Aaron F. Alexander-Bloch, Christos Davatzikos, Damien A. Fair, Ruben C. Gur, Raquel E. Gur, Hongming Li, Michael P. Milham, Tyler M. Moore, Kristin Murtha, Linden Parkes, Sharon L. Thompson-Schill, Sheila Shanmugan, Russell T. Shinohara, Sarah M. Weinstein, Danielle S. Bassett, Yong Fan, and Theodore D. Satterthwaite

Subjects
Science
Abstract

Studies of brain network development typically focus on a single scale. Here, the authors derived personalized functional networks across scales, and find that network development systematically adheres to and strengthens hierarchical cortical organization.

Published
2022
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32. The Diverse Club: The Integrative Core of Complex Networks

Author

Bertolero, M. A., Yeo, B. T. T., and D'Esposito, M.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Physics and Society
Abstract

A complex system can be represented and analyzed as a network, where nodes represent the units of the network and edges represent connections between those units. For example, a brain network represents neurons as nodes and axons between neurons as edges. In many networks, some nodes have a disproportionately high number of edges. These nodes also have many edges between each other, and are referred to as the rich club. In many different networks, the nodes of this club are assumed to support global network integration. However, another set of nodes potentially exhibits a connectivity structure that is more advantageous to global network integration. Here, in a myriad of different biological and man-made networks, we discover the diverse club--a set of nodes that have edges diversely distributed across the network. The diverse club exhibits, to a greater extent than the rich club, properties consistent with an integrative network function--these nodes are more highly interconnected and their edges are more critical for efficient global integration. Moreover, we present a generative evolutionary network model that produces networks with a diverse club but not a rich club, thus demonstrating that these two clubs potentially evolved via distinct selection pressures. Given the variety of different networks that we analyzed--the c. elegans, the macaque brain, the human brain, the United States power grid, and global air traffic--the diverse club appears to be ubiquitous in complex networks. These results warrant the distinction and analysis of two critical clubs of nodes in all complex systems.

Published
2017
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34. A mechanistic model of connector hubs, modularity and cognition

Author

Bertolero, Maxwell A, Yeo, BT Thomas, Bassett, Danielle S, and D’Esposito, Mark

Subjects
Biological Psychology, Cognitive and Computational Psychology, Psychology, Neurosciences, Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, Biomedical and clinical sciences, Health sciences
Abstract

The human brain network is modular-comprised of communities of tightly interconnected nodes1. This network contains local hubs, which have many connections within their own communities, and connector hubs, which have connections diversely distributed across communities2,3. A mechanistic understanding of these hubs and how they support cognition has not been demonstrated. Here, we leveraged individual differences in hub connectivity and cognition. We show that a model of hub connectivity accurately predicts the cognitive performance of 476 individuals in four distinct tasks. Moreover, there is a general optimal network structure for cognitive performance-individuals with diversely connected hubs and consequent modular brain networks exhibit increased cognitive performance, regardless of the task. Critically, we find evidence consistent with a mechanistic model in which connector hubs tune the connectivity of their neighbors to be more modular while allowing for task appropriate information integration across communities, which increases global modularity and cognitive performance.

Published
2018

36. Dissociable multi-scale patterns of development in personalized brain networks

Author

Pines, Adam R., Larsen, Bart, Cui, Zaixu, Sydnor, Valerie J., Bertolero, Maxwell A., Adebimpe, Azeez, Alexander-Bloch, Aaron F., Davatzikos, Christos, Fair, Damien A., Gur, Ruben C., Gur, Raquel E., Li, Hongming, Milham, Michael P., Moore, Tyler M., Murtha, Kristin, Parkes, Linden, Thompson-Schill, Sharon L., Shanmugan, Sheila, Shinohara, Russell T., Weinstein, Sarah M., Bassett, Danielle S., Fan, Yong, and Satterthwaite, Theodore D.

Published
2022
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37. Deciphering the functional specialization of whole-brain spatiomolecular gradients in the adult brain

Author

Vogel, Jacob W., primary, Alexander-Bloch, Aaron F., additional, Wagstyl, Konrad, additional, Bertolero, Maxwell A., additional, Markello, Ross D., additional, Pines, Adam, additional, Sydnor, Valerie J., additional, Diaz-Papkovich, Alex, additional, Hansen, Justine Y., additional, Evans, Alan C., additional, Bernhardt, Boris, additional, Misic, Bratislav, additional, Satterthwaite, Theodore D., additional, and Seidlitz, Jakob, additional

Published
2024
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39. Curation of BIDS (CuBIDS): A workflow and software package for streamlining reproducible curation of large BIDS datasets

Author

Sydney Covitz, Tinashe M. Tapera, Azeez Adebimpe, Aaron F. Alexander-Bloch, Maxwell A. Bertolero, Eric Feczko, Alexandre R. Franco, Raquel E. Gur, Ruben C. Gur, Timothy Hendrickson, Audrey Houghton, Kahini Mehta, Kristin Murtha, Anders J. Perrone, Tim Robert-Fitzgerald, Jenna M. Schabdach, Russell T Shinohara, Jacob W. Vogel, Chenying Zhao, Damien A. Fair, Michael P. Milham, Matthew Cieslak, and Theodore D. Satterthwaite

Subjects
BIDS, MRI, Brain, Neuroimaging, Software, Curation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

The Brain Imaging Data Structure (BIDS) is a specification accompanied by a software ecosystem that was designed to create reproducible and automated workflows for processing neuroimaging data. BIDS Apps flexibly build workflows based on the metadata detected in a dataset. However, even BIDS valid metadata can include incorrect values or omissions that result in inconsistent processing across sessions. Additionally, in large-scale, heterogeneous neuroimaging datasets, hidden variability in metadata is difficult to detect and classify. To address these challenges, we created a Python-based software package titled “Curation of BIDS” (CuBIDS), which provides an intuitive workflow that helps users validate and manage the curation of their neuroimaging datasets. CuBIDS includes a robust implementation of BIDS validation that scales to large samples and incorporates DataLad––a version control software package for data––as an optional dependency to ensure reproducibility and provenance tracking throughout the entire curation process. CuBIDS provides tools to help users perform quality control on their images’ metadata and identify unique combinations of imaging parameters. Users can then execute BIDS Apps on a subset of participants that represent the full range of acquisition parameters that are present, accelerating pipeline testing on large datasets.

Published
2022
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40. The Human Thalamus Is an Integrative Hub for Functional Brain Networks

Author

Hwang, Kai, Bertolero, Maxwell A, Liu, William B, and D'Esposito, Mark

Subjects
Mental Health, Neurosciences, Behavioral and Social Science, Brain Disorders, Basic Behavioral and Social Science, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Adult, Brain Mapping, Cerebral Cortex, Cognition, Female, Humans, Male, Nerve Net, Neural Pathways, Thalamus, Young Adult, brain networks, diaschisis, functional connectivity, graph theory, thalamus, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery
Abstract

The thalamus is globally connected with distributed cortical regions, yet the functional significance of this extensive thalamocortical connectivity remains largely unknown. By performing graph-theoretic analyses on thalamocortical functional connectivity data collected from human participants, we found that most thalamic subdivisions display network properties that are capable of integrating multimodal information across diverse cortical functional networks. From a meta-analysis of a large dataset of functional brain-imaging experiments, we further found that the thalamus is involved in multiple cognitive functions. Finally, we found that focal thalamic lesions in humans have widespread distal effects, disrupting the modular organization of cortical functional networks. This converging evidence suggests that the human thalamus is a critical hub region that could integrate diverse information being processed throughout the cerebral cortex as well as maintain the modular structure of cortical functional networks.SIGNIFICANCE STATEMENT The thalamus is traditionally viewed as a passive relay station of information from sensory organs or subcortical structures to the cortex. However, the thalamus has extensive connections with the entire cerebral cortex, which can also serve to integrate information processing between cortical regions. In this study, we demonstrate that multiple thalamic subdivisions display network properties that are capable of integrating information across multiple functional brain networks. Moreover, the thalamus is engaged by tasks requiring multiple cognitive functions. These findings support the idea that the thalamus is involved in integrating information across cortical networks.

Published
2017

41. The diverse club

Author

Bertolero, MA, Yeo, BTT, and D’Esposito, M

Subjects
Information and Computing Sciences, Physical Sciences, Machine Learning, Neurosciences, Air Travel, Animals, Axons, Brain, Caenorhabditis elegans, Electric Power Supplies, Humans, Macaca, Nerve Net, White Matter
Abstract

A complex system can be represented and analyzed as a network, where nodes represent the units of the network and edges represent connections between those units. For example, a brain network represents neurons as nodes and axons between neurons as edges. In many networks, some nodes have a disproportionately high number of edges as well as many edges between each other and are referred to as the "rich club". In many different networks, the nodes of this club are assumed to support global network integration. Here we show that another set of nodes, which have edges diversely distributed across the network, form a "diverse club". The diverse club exhibits, to a greater extent than the rich club, properties consistent with an integrative network function-these nodes are more highly interconnected and their edges are more critical for efficient global integration. Finally, these two clubs potentially evolved via distinct selection pressures.

Published
2017

44. Turtles and Tortoises Are in Trouble

Author

Stanford, Craig B., Iverson, John B., Rhodin, Anders G.J., Paul van Dijk, Peter, Mittermeier, Russell A., Kuchling, Gerald, Berry, Kristin H., Bertolero, Alberto, Bjorndal, Karen A., Blanck, Torsten E.G., Buhlmann, Kurt A., Burke, Russell L., Congdon, Justin D., Diagne, Tomas, Edwards, Taylor, Eisemberg, Carla C., Ennen, Josh R., Forero-Medina, Germán, Frankel, Matt, Fritz, Uwe, Gallego-García, Natalia, Georges, Arthur, Gibbons, J. Whitfield, Gong, Shiping, Goode, Eric V., Shi, Haitao T., Hoang, Ha, Hofmeyr, Margaretha D., Horne, Brian D., Hudson, Rick, Juvik, James O., Kiester, Ross A., Koval, Patricia, Le, Minh, Lindeman, Peter V., Lovich, Jeffrey E., Luiselli, Luca, McCormack, Timothy E.M., Meyer, George A., Páez, Vivian P., Platt, Kalyar, Platt, Steven G., Pritchard, Peter C.H., Quinn, Hugh R., Roosenburg, Willem M., Seminoff, Jeffrey A., Shaffer, H. Bradley, Spencer, Ricky, Van Dyke, James U., Vogt, Richard C., and Walde, Andrew D.

Published
2020
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46. Multimodal network dynamics underpinning working memory

Author

Andrew C. Murphy, Maxwell A. Bertolero, Lia Papadopoulos, David M. Lydon-Staley, and Danielle S. Bassett

Subjects
Science
Abstract

Working memory is a critical component of executive function that allows people to complete complex tasks in the moment. Here, the authors show that this ability is underpinned by two newly defined brain networks.

Published
2020
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47. Model-based stationarity filtering of long-term memory data applied to resting-state blood-oxygen-level-dependent signal

Author

Ishita Rai Bansal, Arian Ashourvan, Maxwell Bertolero, Danielle S. Bassett, and Sérgio Pequito

Subjects
Medicine, Science
Abstract

Resting-state blood-oxygen-level-dependent (BOLD) signal acquired through functional magnetic resonance imaging is a proxy of neural activity and a key mechanism for assessing neurological conditions. Therefore, practical tools to filter out artefacts that can compromise the assessment are required. On the one hand, a variety of tailored methods to preprocess the data to deal with identified sources of noise (e.g., head motion, heart beating, and breathing, just to mention a few) are in place. But, on the other hand, there might be unknown sources of unstructured noise present in the data. Therefore, to mitigate the effects of such unstructured noises, we propose a model-based filter that explores the statistical properties of the underlying signal (i.e., long-term memory). Specifically, we consider autoregressive fractional integrative process filters. Remarkably, we provide evidence that such processes can model the signals at different regions of interest to attain stationarity. Furthermore, we use a principled analysis where a ground-truth signal with statistical properties similar to the BOLD signal under the injection of noise is retrieved using the proposed filters. Next, we considered preprocessed (i.e., the identified sources of noise removed) resting-state BOLD data of 98 subjects from the Human Connectome Project. Our results demonstrate that the proposed filters decrease the power in the higher frequencies. However, unlike the low-pass filters, the proposed filters do not remove all high-frequency information, instead they preserve process-related higher frequency information. Additionally, we considered four different metrics (power spectrum, functional connectivity using the Pearson’s correlation, coherence, and eigenbrains) to infer the impact of such filter. We provided evidence that whereas the first three keep most of the features of interest from a neuroscience perspective unchanged, the latter exhibits some variations that could be due to the sporadic activity filtered out.

Published
2022

48. External drivers of BOLD signal’s non-stationarity

Author

Arian Ashourvan, Sérgio Pequito, Maxwell Bertolero, Jason Z. Kim, Danielle S. Bassett, and Brian Litt

Subjects
Medicine, Science
Abstract

A fundamental challenge in neuroscience is to uncover the principles governing how the brain interacts with the external environment. However, assumptions about external stimuli fundamentally constrain current computational models. We show in silico that unknown external stimulation can produce error in the estimated linear time-invariant dynamical system. To address these limitations, we propose an approach to retrieve the external (unknown) input parameters and demonstrate that the estimated system parameters during external input quiescence uncover spatiotemporal profiles of external inputs over external stimulation periods more accurately. Finally, we unveil the expected (and unexpected) sensory and task-related extra-cortical input profiles using functional magnetic resonance imaging data acquired from 96 subjects (Human Connectome Project) during the resting-state and task scans. This dynamical systems model of the brain offers information on the structure and dimensionality of the BOLD signal’s external drivers and shines a light on the likely external sources contributing to the BOLD signal’s non-stationarity. Our findings show the role of exogenous inputs in the BOLD dynamics and highlight the importance of accounting for external inputs to unravel the brain’s time-varying functional dynamics.

Published
2022

49. It’s not all abundance: Detectability and accessibility of food also explain breeding investment in long-lived marine animals

Author

Enric Real, Daniel Orol, Albert Bertolero, José Manuel Igual, Ana Sanz-Aguilar, Meritxell Genovart, Manuel Hidalgo, and Giacomo Tavecchia

Subjects
Medicine, Science
Abstract

Large-scale climatic indices are extensively used as predictors of ecological processes, but the mechanisms and the spatio-temporal scales at which climatic indices influence these processes are often speculative. Here, we use long-term data to evaluate how a measure of individual breeding investment (the egg volume) of three long-lived and long-distance-migrating seabirds is influenced by i) a large-scale climatic index (the North Atlantic Oscillation) and ii) local-scale variables (food abundance, foraging conditions, and competition). Winter values of the North Atlantic Oscillation did not correlate with local-scale variables measured in spring, but surprisingly, both had a high predictive power of the temporal variability of the egg volume in the three study species, even though they have different life-history strategies. The importance of the winter North Atlantic Oscillation suggests carry-over effects of winter conditions on subsequent breeding investment. Interestingly, the most important local-scale variables measured in spring were associated with food detectability (foraging conditions) and the factors influencing its accessibility (foraging conditions and competition by density-dependence). Large-scale climatic indices may work better as predictors of foraging conditions when organisms perform long distance migrations, while local-scale variables are more appropriate when foraging areas are more restricted (e.g. during the breeding season). Contrary to what is commonly assumed, food abundance does not directly translate into food intake and its detectability and accessibility should be considered in the study of food-related ecological processes.

Published
2022

50. The modular and integrative functional architecture of the human brain

Author

Bertolero, Maxwell A, Yeo, BT Thomas, and D’Esposito, Mark

Subjects
Biological Psychology, Cognitive and Computational Psychology, Psychology, Behavioral and Social Science, Neurosciences, Basic Behavioral and Social Science, Bioengineering, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Mental health, Brain, Cognition, Humans, Magnetic Resonance Imaging, modularity, hubs, cognition, graph theory, network
Abstract

Network-based analyses of brain imaging data consistently reveal distinct modules and connector nodes with diverse global connectivity across the modules. How discrete the functions of modules are, how dependent the computational load of each module is to the other modules' processing, and what the precise role of connector nodes is for between-module communication remains underspecified. Here, we use a network model of the brain derived from resting-state functional MRI (rs-fMRI) data and investigate the modular functional architecture of the human brain by analyzing activity at different types of nodes in the network across 9,208 experiments of 77 cognitive tasks in the BrainMap database. Using an author-topic model of cognitive functions, we find a strong spatial correspondence between the cognitive functions and the network's modules, suggesting that each module performs a discrete cognitive function. Crucially, activity at local nodes within the modules does not increase in tasks that require more cognitive functions, demonstrating the autonomy of modules' functions. However, connector nodes do exhibit increased activity when more cognitive functions are engaged in a task. Moreover, connector nodes are located where brain activity is associated with many different cognitive functions. Connector nodes potentially play a role in between-module communication that maintains the modular function of the brain. Together, these findings provide a network account of the brain's modular yet integrated implementation of cognitive functions.

Published
2015

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