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1. Unlearning Information Bottleneck: Machine Unlearning of Systematic Patterns and Biases

Author

Han, Ling, Huang, Hao, Scheinost, Dustin, Hartley, Mary-Anne, and Martínez, María Rodríguez

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Effective adaptation to distribution shifts in training data is pivotal for sustaining robustness in neural networks, especially when removing specific biases or outdated information, a process known as machine unlearning. Traditional approaches typically assume that data variations are random, which makes it difficult to adjust the model parameters accurately to remove patterns and characteristics from unlearned data. In this work, we present Unlearning Information Bottleneck (UIB), a novel information-theoretic framework designed to enhance the process of machine unlearning that effectively leverages the influence of systematic patterns and biases for parameter adjustment. By proposing a variational upper bound, we recalibrate the model parameters through a dynamic prior that integrates changes in data distribution with an affordable computational cost, allowing efficient and accurate removal of outdated or unwanted data patterns and biases. Our experiments across various datasets, models, and unlearning methods demonstrate that our approach effectively removes systematic patterns and biases while maintaining the performance of models post-unlearning.

Published
2024

6. Brain age prediction and deviations from normative trajectories in the neonatal connectome

Author

Huili Sun, Saloni Mehta, Milana Khaitova, Bin Cheng, Xuejun Hao, Marisa Spann, and Dustin Scheinost

Subjects
Science
Abstract

Abstract Structural and functional connectomes undergo rapid changes during the third trimester and the first month of postnatal life. Despite progress, our understanding of the developmental trajectories of the connectome in the perinatal period remains incomplete. Brain age prediction uses machine learning to estimate the brain’s maturity relative to normative data. The difference between the individual’s predicted and chronological age—or brain age gap (BAG)—represents the deviation from these normative trajectories. Here, we assess brain age prediction and BAGs using structural and functional connectomes for infants in the first month of life. We use resting-state fMRI and DTI data from 611 infants (174 preterm; 437 term) from the Developing Human Connectome Project (dHCP) and connectome-based predictive modeling to predict postmenstrual age (PMA). Structural and functional connectomes accurately predict PMA for term and preterm infants. Predicted ages from each modality are correlated. At the network level, nearly all canonical brain networks—even putatively later developing ones—generate accurate PMA prediction. Additionally, BAGs are associated with perinatal exposures and toddler behavioral outcomes. Overall, our results underscore the importance of normative modeling and deviations from these models during the perinatal period.

Published
2024
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8. Enhancement attacks in biomedical machine learning

Author

Rosenblatt, Matthew, Dadashkarimi, Javid, and Scheinost, Dustin

Subjects
Statistics - Machine Learning, Computer Science - Cryptography and Security, Computer Science - Machine Learning, Quantitative Biology - Neurons and Cognition
Abstract

The prevalence of machine learning in biomedical research is rapidly growing, yet the trustworthiness of such research is often overlooked. While some previous works have investigated the ability of adversarial attacks to degrade model performance in medical imaging, the ability to falsely improve performance via recently-developed "enhancement attacks" may be a greater threat to biomedical machine learning. In the spirit of developing attacks to better understand trustworthiness, we developed two techniques to drastically enhance prediction performance of classifiers with minimal changes to features: 1) general enhancement of prediction performance, and 2) enhancement of a particular method over another. Our enhancement framework falsely improved classifiers' accuracy from 50% to almost 100% while maintaining high feature similarities between original and enhanced data (Pearson's r's>0.99). Similarly, the method-specific enhancement framework was effective in falsely improving the performance of one method over another. For example, a simple neural network outperformed logistic regression by 17% on our enhanced dataset, although no performance differences were present in the original dataset. Crucially, the original and enhanced data were still similar (r=0.99). Our results demonstrate the feasibility of minor data manipulations to achieve any desired prediction performance, which presents an interesting ethical challenge for the future of biomedical machine learning. These findings emphasize the need for more robust data provenance tracking and other precautionary measures to ensure the integrity of biomedical machine learning research., Comment: 12 pages, 3 figures

Published
2023

9. Brain-phenotype predictions of language and executive function can survive across diverse real-world data: Dataset shifts in developmental populations

Author

Brendan D. Adkinson, Matthew Rosenblatt, Javid Dadashkarimi, Link Tejavibulya, Rongtao Jiang, Stephanie Noble, and Dustin Scheinost

Subjects
Machine learning, Cognition, Dataset shift, Diversity, Harmonization, Childhood, Neurophysiology and neuropsychology, QP351-495
Abstract

Predictive modeling potentially increases the reproducibility and generalizability of neuroimaging brain-phenotype associations. Yet, the evaluation of a model in another dataset is underutilized. Among studies that undertake external validation, there is a notable lack of attention to generalization across dataset-specific idiosyncrasies (i.e., dataset shifts). Research settings, by design, remove the between-site variations that real-world and, eventually, clinical applications demand. Here, we rigorously test the ability of a range of predictive models to generalize across three diverse, unharmonized developmental samples: the Philadelphia Neurodevelopmental Cohort (n=1291), the Healthy Brain Network (n=1110), and the Human Connectome Project in Development (n=428). These datasets have high inter-dataset heterogeneity, encompassing substantial variations in age distribution, sex, racial and ethnic minority representation, recruitment geography, clinical symptom burdens, fMRI tasks, sequences, and behavioral measures. Through advanced methodological approaches, we demonstrate that reproducible and generalizable brain-behavior associations can be realized across diverse dataset features. Results indicate the potential of functional connectome-based predictive models to be robust despite substantial inter-dataset variability. Notably, for the HCPD and HBN datasets, the best predictions were not from training and testing in the same dataset (i.e., cross-validation) but across datasets. This result suggests that training on diverse data may improve prediction in specific cases. Overall, this work provides a critical foundation for future work evaluating the generalizability of brain-phenotype associations in real-world scenarios and clinical settings.

Published
2024
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11. Overcoming Atlas Heterogeneity in Federated Learning for Cross-Site Connectome-Based Predictive Modeling

Author

Liang, Qinghao, Adkinson, Brendan D., Jiang, Rongtao, Scheinost, Dustin, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Linguraru, Marius George, editor, Dou, Qi, editor, Feragen, Aasa, editor, Giannarou, Stamatia, editor, Glocker, Ben, editor, Lekadir, Karim, editor, and Schnabel, Julia A., editor

Published
2024
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12. An Opportunity to Increase Collaborative Science in Fetal, Infant, and Toddler Neuroimaging.

Author

Korom, Marta, Catalina Camacho, M, Ford, Aiden, Taha, Hana, Scheinost, Dustin, Spann, Marisa, and Vaughn, Kelly

Subjects
Humans, Infant, Child, Preschool, Fetus, Neuroimaging
Abstract

The field of fetal, infant, and toddler (FIT) neuroimaging research—including magnetic resonance imaging (MRI), electroencephalography (EEG), magnetoencephalography, and functional near-infrared spectroscopy, among others—offers pioneering insights into early brain development and has grown in popularity over the past 2 decades. In broader neuroimaging research, multisite collaborative projects, data sharing, and open-source code have increasingly become the norm, fostering big data, consensus standards, and rapid knowledge transfer and development. Given the aforementioned benefits, along with recent initiatives from funding agencies to support multisite and multimodal FIT neuroimaging studies, the FIT field now has the opportunity to establish sustainable, collaborative, and open science practices. By combining data and resources, we can tackle the most pressing issues of the FIT field, including small effect sizes, replicability problems, generalizability issues, and the lack of field standards for data collection, processing, and analysis—together. Thus, the goals of this commentary are to highlight some of the potential barriers that have waylaid these efforts and to discuss the emerging solutions that have the potential to revolutionize how we work together to study the developing brain early in life.

Published
2023

14. The brain structure, inflammatory, and genetic mechanisms mediate the association between physical frailty and depression

Author

Rongtao Jiang, Stephanie Noble, Matthew Rosenblatt, Wei Dai, Jean Ye, Shu Liu, Shile Qi, Vince D. Calhoun, Jing Sui, and Dustin Scheinost

Subjects
Science
Abstract

Abstract Cross-sectional studies have demonstrated strong associations between physical frailty and depression. However, the evidence from prospective studies is limited. Here, we analyze data of 352,277 participants from UK Biobank with 12.25-year follow-up. Compared with non-frail individuals, pre-frail and frail individuals have increased risk for incident depression independent of many putative confounds. Altogether, pre-frail and frail individuals account for 20.58% and 13.16% of depression cases by population attributable fraction analyses. Higher risks are observed in males and individuals younger than 65 years than their counterparts. Mendelian randomization analyses support a potential causal effect of frailty on depression. Associations are also observed between inflammatory markers, brain volumes, and incident depression. Moreover, these regional brain volumes and three inflammatory markers—C-reactive protein, neutrophils, and leukocytes—significantly mediate associations between frailty and depression. Given the scarcity of curative treatment for depression and the high disease burden, identifying potential modifiable risk factors of depression, such as frailty, is needed.

Published
2024
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15. Impact of postnatal weight gain on brain white matter maturation in very preterm infants.

Author

Bobba, Pratheek, Weber, Clara, Higaki, Adrian, Mukherjee, Pratik, Scheinost, Dustin, Constable, R, Ment, Laura, Taylor, Sarah, and Payabvash, Seyedmehdi

Subjects
diffusion imaging, preterm infants, white matter maturation, Infant, Infant, Newborn, Humans, Pregnancy, Female, White Matter, Infant, Premature, Diffusion Tensor Imaging, Birth Weight, Brain
Abstract

BACKGROUND AND PURPOSE: Very preterm infants (VPIs,

Published
2023

16. Autism spectrum disorder-specific changes in white matter connectome edge density based on functionally defined nodes.

Author

Weber, Clara, Lake, Evelyn, Haider, Stefan, Mozayan, Ali, Bobba, Pratheek, Scheinost, Dustin, Constable, Robert, Ment, Laura, Payabvash, Seyedmehdi, and Mukherjee, Pratik

Subjects
DTI, autism spectrum disorder, connectome, microstructure, neurodevelopment
Abstract

INTRODUCTION: Autism spectrum disorder (ASD) is associated with both functional and microstructural connectome disruptions. We deployed a novel methodology using functionally defined nodes to guide white matter (WM) tractography and identify ASD-related microstructural connectome changes across the lifespan. METHODS: We used diffusion tensor imaging and clinical data from four studies in the national database for autism research (NDAR) including 155 infants, 102 toddlers, 230 adolescents, and 96 young adults - of whom 264 (45%) were diagnosed with ASD. We applied cortical nodes from a prior fMRI study identifying regions related to symptom severity scores and used these seeds to construct WM fiber tracts as connectome Edge Density (ED) maps. Resulting ED maps were assessed for between-group differences using voxel-wise and tract-based analysis. We then examined the association of ASD diagnosis with ED driven from functional nodes generated from different sensitivity thresholds. RESULTS: In ED derived from functionally guided tractography, we identified ASD-related changes in infants (pFDR ≤ 0.001-0.483). Overall, more wide-spread ASD-related differences were detectable in ED based on functional nodes with positive symptom correlation than negative correlation to ASD, and stricter thresholds for functional nodes resulted in stronger correlation with ASD among infants (z = -6.413 to 6.666, pFDR ≤ 0.001-0.968). Voxel-wise analysis revealed wide-spread ED reductions in central WM tracts of toddlers, adolescents, and adults. DISCUSSION: We detected early changes of aberrant WM development in infants developing ASD when generating microstructural connectome ED map with cortical nodes defined by functional imaging. These were not evident when applying structurally defined nodes, suggesting that functionally guided DTI-based tractography can help identify early ASD-related WM disruptions between cortical regions exhibiting abnormal connectivity patterns later in life. Furthermore, our results suggest a benefit of involving functionally informed nodes in diffusion imaging-based probabilistic tractography, and underline that different age cohorts can benefit from age- and brain development-adapted image processing protocols.

Published
2023

17. A flexible loop in the paxillin LIM3 domain mediates its direct binding to integrin β subunits.

Author

Timo Baade, Marcus Michaelis, Andreas Prestel, Christoph Paone, Nikolai Klishin, Marleen Herbinger, Laura Scheinost, Ruslan Nedielkov, Christof R Hauck, and Heiko M Möller

Subjects
Biology (General), QH301-705.5
Abstract

Integrins are fundamental for cell adhesion and the formation of focal adhesions (FA). Accordingly, these receptors guide embryonic development, tissue maintenance, and haemostasis but are also involved in cancer invasion and metastasis. A detailed understanding of the molecular interactions that drive integrin activation, FA assembly, and downstream signalling cascades is critical. Here, we reveal a direct association of paxillin, a marker protein of FA sites, with the cytoplasmic tails of the integrin β1 and β3 subunits. The binding interface resides in paxillin's LIM3 domain, where based on the NMR structure and functional analyses, a flexible, 7-amino acid loop engages the unstructured part of the integrin cytoplasmic tail. Genetic manipulation of the involved residues in either paxillin or integrin β3 compromises cell adhesion and motility of murine fibroblasts. This direct interaction between paxillin and the integrin cytoplasmic domain identifies an alternative, kindlin-independent mode of integrin outside-in signalling particularly important for integrin β3 function.

Published
2024
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18. A comprehensive study evaluating germline FANCG variants in predisposition to breast and ovarian cancer

Author

Jana Soukupova, Barbora Stastna, Madiha Kanwal, Jan Hojny, Petra Zemankova, Marianna Borecka, Leona Cerna, Marta Cerna, Monika Cerna, Vaclava Curtisova, Tatana Dolezalova, Petra Duskova, Lenka Foretova, Ondrej Havranek, Klara Horackova, Milena Hovhannisyan, Lucie Hruskova, Stepan Chvojka, Marketa Janatova, Maria Janikova, Sandra Jelinkova, Pavel Just, Marta Kalousova, Petra Kleiblova, Marcela Kosarova, Monika Koudova, Jan Kral, Michaela Krausova, Vera Krutilkova, Eva Machackova, Katerina Matejkova, Renata Michalovska, Petr Nehasil, Barbora Nemcova, Jan Novotny, Matous Palek, Pavel Pesek, Marketa Safarikova, Ondrej Scheinost, Drahomira Springer, Lenka Stolarova, Viktor Stranecky, Ivan Subrt, Spiros Tavandzis, Eva Tureckova, Kamila Vesela, Zdenka Vlckova, Michal Vocka, Tomas Zima, Libor Macurek, Zdenek Kleibl, and the CZECANCA consortium

Subjects
breast cancer, Fanconi anemia complementation group G, functional analysis, germline genetic testing, hereditary tumors, ovarian cancer, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Monoallelic germline pathogenic variants (GPVs) in five Fanconi anemia (FA) genes (BRCA1/FANCS, BRCA2/FANCD1, PALB2/FANCN, BRIP1/FANCJ, and RAD51C/FANCO) confer an increased risk of breast (BC) and/or ovarian (OC) cancer, but the role of GPVs in 17 other FA genes remains unclear. Methods Here, we investigated the association of germline variants in FANCG/XRCC9 with BC and OC risk. Results The frequency of truncating GPVs in FANCG did not differ between BC (20/10,204; 0.20%) and OC (8/2966; 0.27%) patients compared to controls (6/3250; 0.18%). In addition, only one out of five tumor samples showed loss‐of‐heterozygosity of the wild‐type FANCG allele. Finally, none of the nine functionally tested rare recurrent missense FANCG variants impaired DNA repair activities (FANCD2 monoubiquitination and FANCD2 foci formation) upon DNA damage, in contrast to all tested FANCG truncations. Conclusion Our study suggests that heterozygous germline FANCG variants are unlikely to contribute to the development of BC or OC.

Published
2024
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20. Data leakage inflates prediction performance in connectome-based machine learning models

Author

Matthew Rosenblatt, Link Tejavibulya, Rongtao Jiang, Stephanie Noble, and Dustin Scheinost

Subjects
Science
Abstract

Abstract Predictive modeling is a central technique in neuroimaging to identify brain-behavior relationships and test their generalizability to unseen data. However, data leakage undermines the validity of predictive models by breaching the separation between training and test data. Leakage is always an incorrect practice but still pervasive in machine learning. Understanding its effects on neuroimaging predictive models can inform how leakage affects existing literature. Here, we investigate the effects of five forms of leakage–involving feature selection, covariate correction, and dependence between subjects–on functional and structural connectome-based machine learning models across four datasets and three phenotypes. Leakage via feature selection and repeated subjects drastically inflates prediction performance, whereas other forms of leakage have minor effects. Furthermore, small datasets exacerbate the effects of leakage. Overall, our results illustrate the variable effects of leakage and underscore the importance of avoiding data leakage to improve the validity and reproducibility of predictive modeling.

Published
2024
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22. A deep intronic recurrent CHEK2 variant c.1009-118_1009-87delinsC affects pre-mRNA splicing and contributes to hereditary breast cancer predisposition

Author

Petra Zemankova, Marta Cerna, Klara Horackova, Corinna Ernst, Jana Soukupova, Marianna Borecka, Britta Blümcke, Leona Cerna, Monika Cerna, Vaclava Curtisova, Tatana Dolezalova, Petra Duskova, Lenka Dvorakova, Lenka Foretova, Ondrej Havranek, Jan Hauke, Eric Hahnen, Miloslava Hodulova, Milena Hovhannisyan, Lucie Hruskova, Marketa Janatova, Maria Janikova, Sandra Jelinkova, Pavel Just, Marcela Kosarova, Monika Koudova, Vera Krutilkova, Eva Machackova, Katerina Matejkova, Renata Michalovska, Adela Misove, Petr Nehasil, Barbora Nemcova, Jan Novotny, Ales Panczak, Pavel Pesek, Ondrej Scheinost, Drahomira Springer, Barbora Stastna, Viktor Stranecky, Ivan Subrt, Spiros Tavandzis, Eva Tureckova, Kamila Vesela, Zdenka Vlckova, Michal Vocka, Barbara Wappenschmidt, Tomas Zima, Zdenek Kleibl, and Petra Kleiblova

Subjects
Deep intronic CHEK2 variant, Breast cancer, NGS, RNA analysis, Genetic testing, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Germline CHEK2 pathogenic variants confer an increased risk of female breast cancer (FBC). Here we describe a recurrent germline intronic variant c.1009-118_1009-87delinsC, which showed a splice acceptor shift in RNA analysis, introducing a premature stop codon (p.Tyr337PhefsTer37).The variant was found in 21/10,204 (0.21%) Czech FBC patients compared to 1/3250 (0.03%) controls (p = 0.04) and in 4/3639 (0.11%) FBC patients from an independent German dataset. In addition, we found this variant in 5/2966 (0.17%) Czech (but none of the 443 German) ovarian cancer patients, three of whom developed early-onset tumors.Based on these observations, we classified this variant as likely pathogenic.

Published
2024
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23. Data-driven mapping between functional connectomes using optimal transport

Author

Dadashkarimi, Javid, Karbasi, Amin, and Scheinost, Dustin

Subjects
Quantitative Biology - Neurons and Cognition, Computer Science - Machine Learning
Abstract

Functional connectomes derived from functional magnetic resonance imaging have long been used to understand the functional organization of the brain. Nevertheless, a connectome is intrinsically linked to the atlas used to create it. In other words, a connectome generated from one atlas is different in scale and resolution compared to a connectome generated from another atlas. Being able to map connectomes and derived results between different atlases without additional pre-processing is a crucial step in improving interpretation and generalization between studies that use different atlases. Here, we use optimal transport, a powerful mathematical technique, to find an optimum mapping between two atlases. This mapping is then used to transform time series from one atlas to another in order to reconstruct a connectome. We validate our approach by comparing transformed connectomes against their "gold-standard" counterparts (i.e., connectomes generated directly from an atlas) and demonstrate the utility of transformed connectomes by applying these connectomes to predictive models based on a different atlas. We show that these transformed connectomes are significantly similar to their "gold-standard" counterparts and maintain individual differences in brain-behavior associations, demonstrating both the validity of our approach and its utility in downstream analyses. Overall, our approach is a promising avenue to increase the generalization of connectome-based results across different atlases.

Published
2021

27. Age-dependent white matter microstructural disintegrity in autism spectrum disorder

Author

Weber, Clara F, Lake, Evelyn MR, Haider, Stefan P, Mozayan, Ali, Mukherjee, Pratik, Scheinost, Dustin, Bamford, Nigel S, Ment, Laura, Constable, Todd, and Payabvash, Seyedmehdi

Subjects
Paediatrics, Biomedical and Clinical Sciences, Prevention, Brain Disorders, Intellectual and Developmental Disabilities (IDD), Mental Health, Neurosciences, Clinical Research, Biomedical Imaging, Pediatric, Autism, Mental health, autism, age, diffusion tensor imaging, connectome, white matter, Psychology, Cognitive Sciences, Biological psychology
Abstract

There has been increasing evidence of White Matter (WM) microstructural disintegrity and connectome disruption in Autism Spectrum Disorder (ASD). We evaluated the effects of age on WM microstructure by examining Diffusion Tensor Imaging (DTI) metrics and connectome Edge Density (ED) in a large dataset of ASD and control patients from different age cohorts. N = 583 subjects from four studies from the National Database of Autism Research were included, representing four different age groups: (1) A Longitudinal MRI Study of Infants at Risk of Autism [infants, median age: 7 (interquartile range 1) months, n = 155], (2) Biomarkers of Autism at 12 months [toddlers, 32 (11)m, n = 102], (3) Multimodal Developmental Neurogenetics of Females with ASD [adolescents, 13.1 (5.3) years, n = 230], (4) Atypical Late Neurodevelopment in Autism [young adults, 19.1 (10.7)y, n = 96]. For each subject, we created Fractional Anisotropy (FA), Mean- (MD), Radial- (RD), and Axial Diffusivity (AD) maps as well as ED maps. We performed voxel-wise and tract-based analyses to assess the effects of age, ASD diagnosis and sex on DTI metrics and connectome ED. We also optimized, trained, tested, and validated different combinations of machine learning classifiers and dimensionality reduction algorithms for prediction of ASD diagnoses based on tract-based DTI and ED metrics. There is an age-dependent increase in FA and a decline in MD and RD across WM tracts in all four age cohorts, as well as an ED increase in toddlers and adolescents. After correction for age and sex, we found an ASD-related decrease in FA and ED only in adolescents and young adults, but not in infants or toddlers. While DTI abnormalities were mostly limited to the corpus callosum, connectomes showed a more widespread ASD-related decrease in ED. Finally, the best performing machine-leaning classification model achieved an area under the receiver operating curve of 0.70 in an independent validation cohort. Our results suggest that ASD-related WM microstructural disintegrity becomes evident in adolescents and young adults-but not in infants and toddlers. The ASD-related decrease in ED demonstrates a more widespread involvement of the connectome than DTI metrics, with the most striking differences being localized in the corpus callosum.

Published
2022

31. Gradient-Based Enhancement Attacks in Biomedical Machine Learning

Author

Rosenblatt, Matthew, Dadashkarimi, Javid, Scheinost, Dustin, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Wesarg, Stefan, editor, Puyol Antón, Esther, editor, Baxter, John S. H., editor, Erdt, Marius, editor, Drechsler, Klaus, editor, Oyarzun Laura, Cristina, editor, Freiman, Moti, editor, Chen, Yufei, editor, Rekik, Islem, editor, Eagleson, Roy, editor, Feragen, Aasa, editor, King, Andrew P., editor, Cheplygina, Veronika, editor, Ganz-Benjaminsen, Melani, editor, Ferrante, Enzo, editor, Glocker, Ben, editor, Moyer, Daniel, editor, and Petersen, Eikel, editor

Published
2023
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33. Smooth graph learning for functional connectivity estimation

Author

Gao, Siyuan, Xia, Xinyue, Scheinost, Dustin, and Mishne, Gal

Subjects
Biomedical and Clinical Sciences, Health Sciences, Neurosciences, Algorithms, Connectome, Datasets as Topic, Humans, Intelligence, Magnetic Resonance Imaging, Mathematics, Reproducibility of Results, Support Vector Machine, Functional connectivity, FMRI Fingerprinting, Reliability, Small-world, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biomedical and clinical sciences, Health sciences
Abstract

Functional connectivity (FC) estimated from functional magnetic resonance imaging (fMRI) signals is important in understanding neural representation and information processing in cortical networks. However, due to a lack of "ground truth" FC pattern, the reliability and robustness of FC estimates are usually examined in downstream FC analysis tasks, such as performing participant's identification (also known as "fingerprinting"). In this paper, we propose to learn FC via a smooth graph learning framework. In particular, we treat each time frame of the fMRI time series as a graph signal on an underlying functional brain graph, and estimate the smooth graph functional connectivity (SGFC) by learning the weighted graph adjacency matrix based on graph signal smoothness assumption. We demonstrate that our approach gives rise to a natural and sparse graph representation of FC from which reliable graph measures can be extracted. Reliability of SGFC is evaluated in the context of fingerprinting and compared to correlation FC (CFC). SGFC achieves higher fingerprinting accuracy across several different experiment settings; the improvement is even more significant when a shorter fMRI scanning length is used for FC estimation. In addition to being reliable, we also validate the cognitive relevance of SGFC by using it to predict fluid intelligence. Finally, in evaluating topological measures of the sparse graph, SGFC reveals a more small-world and modular structure compared to CFC. Together, our results suggest that the smooth graph learning framework produces a naturally sparse, reliable, and cognitive-relevant representation of functional connectivity.

Published
2021

34. Nonlinear manifold learning in functional magnetic resonance imaging uncovers a low‐dimensional space of brain dynamics

Author

Gao, Siyuan, Mishne, Gal, and Scheinost, Dustin

Subjects
Biomedical Imaging, Neurosciences, Mental health, Neurological, Adult, Brain, Connectome, Functional Neuroimaging, Humans, Machine Learning, Magnetic Resonance Imaging, Mental Processes, diffusion maps, dynamic connectivity, integration, participation coefficient, segregation, Cognitive Sciences, Experimental Psychology
Abstract

Large-scale brain dynamics are believed to lie in a latent, low-dimensional space. Typically, the embeddings of brain scans are derived independently from different cognitive tasks or resting-state data, ignoring a potentially large-and shared-portion of this space. Here, we establish that a shared, robust, and interpretable low-dimensional space of brain dynamics can be recovered from a rich repertoire of task-based functional magnetic resonance imaging (fMRI) data. This occurs when relying on nonlinear approaches as opposed to traditional linear methods. The embedding maintains proper temporal progression of the tasks, revealing brain states and the dynamics of network integration. We demonstrate that resting-state data embeds fully onto the same task embedding, indicating similar brain states are present in both task and resting-state data. Our findings suggest analysis of fMRI data from multiple cognitive tasks in a low-dimensional space is possible and desirable.

Published
2021

40. Network controllability of structural connectomes in the neonatal brain

Author

Huili Sun, Rongtao Jiang, Wei Dai, Alexander J. Dufford, Stephanie Noble, Marisa N. Spann, Shi Gu, and Dustin Scheinost

Subjects
Science
Abstract

Abstract White matter connectivity supports diverse cognitive demands by efficiently constraining dynamic brain activity. This efficiency can be inferred from network controllability, which represents the ease with which the brain moves between distinct mental states based on white matter connectivity. However, it remains unclear how brain networks support diverse functions at birth, a time of rapid changes in connectivity. Here, we investigate the development of network controllability during the perinatal period and the effect of preterm birth in 521 neonates. We provide evidence that elements of controllability are exhibited in the infant’s brain as early as the third trimester and develop rapidly across the perinatal period. Preterm birth disrupts the development of brain networks and altered the energy required to drive state transitions at different levels. In addition, controllability at birth is associated with cognitive ability at 18 months. Our results suggest network controllability develops rapidly during the perinatal period to support cognitive demands but could be altered by environmental impacts like preterm birth.

Published
2023
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41. Signatures of technetium oxidation states: a new approach

Author

Bauters, Stephen, Scheinost, Andreas C., Schmeide, Katja, Weiss, Stephan, Dardenne, Kathy, Rothe, Jörg, Mayordomo, Natalia, Steudtner, Robin, Stumpf, Thorsten, Abram, Ulrich, Butorin, Sergei M., and Kvashnina, Kristina O.

Subjects
Physics - Chemical Physics
Abstract

A general strategy for the determination of Tc oxidation state by new approach involving X-ray absorption near edge spectroscopy (XANES) at the Tc L3 edge is shown. A comprehensive series of 99Tc compounds, ranging from oxidation states I to VII, was measured and subsequently simulated within the framework of crystal-field multiplet theory. The observable trends in the absorption edge energy shift in combination with the spectral shape allow for a deeper understanding of complicated Tc coordination chemistry. This approach can be extended to numerous studies of Tc systems as this method is one of the most sensitive methods for accurate Tc oxidation state and ligand characterization., Comment: 21/10/2020: Corrected a spelling error in the author list. Added affiliations in pdf file

Published
2020
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42. Towards the surface hydroxyl species in CeO$_2$ nanoparticles

Author

Plakhova, Tatiana V, Romanchuk, Anna Yu, Butorin, Sergei M, Konyukhova, Anastasia D, Egorov, Alexander V, Shiryaev, Andrey A, Baranchikov, Alexander E, Dorovatovskii, Pavel V, Huthwelker, Thomas, Gerber, Evgeny, Bauters, Stephen, Sozarukova, Madina M, Scheinost, Andreas C, Ivanov, Vladimir K, Kalmykov, Stepan N, and Kvashnina, Kristina O

Subjects
Physics - Chemical Physics
Abstract

Understanding the complex chemistry of functional nanomaterials is of fundamental importance. Controlled synthesis and characterization at the atomic level is essential to gain deeper insight into the unique chemical reactivity exhibited by many nanomaterials. Cerium oxide nanoparticles have many industrial and commercial applications,resulting from very strong catalytic, pro-and anti-oxidant activity. However, the identity of the active species and the chemical mechanisms imparted by nanoceria remain elusive, impeding the further development of new applications. Here, we explore the behavior of cerium oxide nanoparticles of different sizes at different temperatures and trace the electronic structure changes by state-of-the-art soft and hard X-ray experiments combined with computational methods. We confirm the absence of the Ce(III) oxidation state at the surface of CeO2nanoparticles, even for particles as small as 2 nm. Synchrotron X-ray absorption experiments at Ce L3and M5edges, combined with X-ray diffraction (XRD), high-resolution transmission electron microscopy (HRTEM) and small angle X-ray scattering (SAXS) and theoretical calculations demonstrate that in addition to the nanoceria charge stability, the formation of hydroxyl groups at the surface profoundly affects the chemical performance of these nanomaterials, Comment: T. Plakhova et al, Nanoscale (2019)

Published
2020
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43. Size Dependence of Lattice Parameter and Electronic Structure in CeO 2 Nanoparticles

Author

Prieur, Damien, Bonani, Walter, Popa, Karin, Walter, Olaf, Kriegsman, Kyle W, Engelhard, Mark H, Guo, Xiaofeng, Eloirdi, Rachel, Gouder, Thomas, Beck, Aaron, Vitova, Tonya, Scheinost, Andreas C, Kvashnina, Kristina, and Martin, Philippe

Subjects
Physics - Chemical Physics
Abstract

Intrinsic properties of a compound (e.g., electronic structure, crystallographic structure, optical and magnetic properties) define notably its chemical and physical behavior. In the case of nanomaterials, these fundamental properties depend on the occurrence of quantum mechanical size effects and on the considerable increase of the surface to bulk ratio. Here, we explore the size dependence of both crystal and electronic properties of CeO2 nanoparticles (NPs) with different sizes by state-of-the art spectroscopic techniques. X-ray diffraction, X-ray photoelectron spectroscopy, and high-energy resolution fluorescence-detection hard X-ray absorption near-edge structure (HERFD-XANES) spectroscopy demonstrate that the as-synthesized NPs crystallize in the fluorite structure and they are predominantly composed of CeIV ions. The strong dependence of the lattice parameter with the NPs size was attributed to the presence of adsorbed species at the NPs surface thanks to Fourier transform infrared spectroscopy and thermogravimetric analysis measurements. In addition, the size dependence of the t2g states in the Ce LIII XANES spectra was experimentally observed by HERFD-XANES and confirmed by theoretical calculations., Comment: Inorganic Chemistry (2020)

Published
2020
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44. The missing pieces of the PuO 2 nanoparticle puzzle

Author

Gerber, Evgeny, Romanchuk, Anna Yu, Pidchenko, Ivan, Amidani, Lucia, Rossberg, Andre, Hennig, Christoph, Vaughan, Gavin B M, Trigub, Alexander, Egorova, Tolganay, Bauters, Stephen, Plakhova, Tatiana, Hunault, Myrtille O J Y, Weiss, Stephan, Butorin, Sergei M, Scheinost, Andreas C, Kalmykov, Stepan N, and Kvashnina, Kristina O

Subjects
Physics - Chemical Physics
Abstract

The nanoscience field often produces results more mystifying than any other discipline. It has been argued that changes in the plutonium dioxide (PuO2) particle size from bulk to nano can have a drastic effect on PuO2 properties. Here we report a full characterization of PuO2 nanoparticles (NPs) at the atomic level and probe their local and electronic structures by a variety of methods available at the synchrotron., Comment: Nanoscale (2020)

Published
2020
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46. Functional connectivity during frustration: a preliminary study of predictive modeling of irritability in youth

Author

Scheinost, Dustin, Dadashkarimi, Javid, Finn, Emily S, Wambach, Caroline G, MacGillivray, Caroline, Roule, Alexandra L, Niendam, Tara A, Pine, Daniel S, Brotman, Melissa A, Leibenluft, Ellen, and Tseng, Wan-Ling

Subjects
Biological Psychology, Psychology, Brain Disorders, Neurosciences, Behavioral and Social Science, Clinical Research, Pediatric, Mental Health, Aetiology, 2.3 Psychological, social and economic factors, Mental health, Adolescent, Attention Deficit Disorder with Hyperactivity, Attention Deficit and Disruptive Behavior Disorders, Child, Frustration, Humans, Irritable Mood, Mood Disorders, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry, Biological psychology
Abstract

Irritability cuts across many pediatric disorders and is a common presenting complaint in child psychiatry; however, its neural mechanisms remain unclear. One core pathophysiological deficit of irritability is aberrant responses to frustrative nonreward. Here, we conducted a preliminary fMRI study to examine the ability of functional connectivity during frustrative nonreward to predict irritability in a transdiagnostic sample. This study included 69 youths (mean age = 14.55 years) with varying levels of irritability across diagnostic groups: disruptive mood dysregulation disorder (n = 20), attention-deficit/hyperactivity disorder (n = 14), anxiety disorder (n = 12), and controls (n = 23). During fMRI, participants completed a frustrating cognitive flexibility task. Frustration was evoked by manipulating task difficulty such that, on trials requiring cognitive flexibility, "frustration" blocks had a 50% error rate and some rigged feedback, while "nonfrustration" blocks had a 10% error rate. Frustration and nonfrustration blocks were randomly interspersed. Child and parent reports of the affective reactivity index were used as dimensional measures of irritability. Connectome-based predictive modeling, a machine learning approach, with tenfold cross-validation was conducted to identify networks predicting irritability. Connectivity during frustration (but not nonfrustration) blocks predicted child-reported irritability (ρ = 0.24, root mean square error = 2.02, p = 0.03, permutation testing, 1000 iterations, one-tailed). Results were adjusted for age, sex, medications, motion, ADHD, and anxiety symptoms. The predictive networks of irritability were primarily within motor-sensory networks; among motor-sensory, subcortical, and salience networks; and between these networks and frontoparietal and medial frontal networks. This study provides preliminary evidence that individual differences in irritability may be associated with functional connectivity during frustration, a phenotype-relevant state.

Published
2021

49. Autism spectrum disorder-specific changes in white matter connectome edge density based on functionally defined nodes

Author

Clara F. Weber, Evelyn M. R. Lake, Stefan P. Haider, Ali Mozayan, Pratheek S. Bobba, Pratik Mukherjee, Dustin Scheinost, Robert T. Constable, Laura Ment, and Seyedmehdi Payabvash

Subjects
autism spectrum disorder, neurodevelopment, DTI, connectome, microstructure, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

IntroductionAutism spectrum disorder (ASD) is associated with both functional and microstructural connectome disruptions. We deployed a novel methodology using functionally defined nodes to guide white matter (WM) tractography and identify ASD-related microstructural connectome changes across the lifespan.MethodsWe used diffusion tensor imaging and clinical data from four studies in the national database for autism research (NDAR) including 155 infants, 102 toddlers, 230 adolescents, and 96 young adults – of whom 264 (45%) were diagnosed with ASD. We applied cortical nodes from a prior fMRI study identifying regions related to symptom severity scores and used these seeds to construct WM fiber tracts as connectome Edge Density (ED) maps. Resulting ED maps were assessed for between-group differences using voxel-wise and tract-based analysis. We then examined the association of ASD diagnosis with ED driven from functional nodes generated from different sensitivity thresholds.ResultsIn ED derived from functionally guided tractography, we identified ASD-related changes in infants (pFDR ≤ 0.001–0.483). Overall, more wide-spread ASD-related differences were detectable in ED based on functional nodes with positive symptom correlation than negative correlation to ASD, and stricter thresholds for functional nodes resulted in stronger correlation with ASD among infants (z = −6.413 to 6.666, pFDR ≤ 0.001–0.968). Voxel-wise analysis revealed wide-spread ED reductions in central WM tracts of toddlers, adolescents, and adults.DiscussionWe detected early changes of aberrant WM development in infants developing ASD when generating microstructural connectome ED map with cortical nodes defined by functional imaging. These were not evident when applying structurally defined nodes, suggesting that functionally guided DTI-based tractography can help identify early ASD-related WM disruptions between cortical regions exhibiting abnormal connectivity patterns later in life. Furthermore, our results suggest a benefit of involving functionally informed nodes in diffusion imaging-based probabilistic tractography, and underline that different age cohorts can benefit from age- and brain development-adapted image processing protocols.

Published
2023
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