Your search keyword '"Brain Mapping"' showing total 5,001 results

1. Quantitative susceptibility mapping in the brain reflects spatial expression of genes involved in iron homeostasis and myelination.

Author

Cohen, Zoe, Lau, Laurance, Ahmed, Maruf, Jack, Clifford, and Liu, Chunlei

Subjects

Allen human brain atlas, QSM, iron, myelination, Humans, Iron, Magnetic Resonance Imaging, Male, Female, Myelin Sheath, Adult, Homeostasis, Ferritins, Brain, Gene Expression, Middle Aged, Cation Transport Proteins, Young Adult, Brain Mapping

Abstract

Quantitative susceptibility mapping (QSM) is an MRI modality used to non-invasively measure iron content in the brain. Iron exhibits a specific anatomically varying pattern of accumulation in the brain across individuals. The highest regions of accumulation are the deep grey nuclei, where iron is stored in paramagnetic molecule ferritin. This form of iron is considered to be what largely contributes to the signal measured by QSM in the deep grey nuclei. It is also known that QSM is affected by diamagnetic myelin contents. Here, we investigate spatial gene expression of iron and myelin related genes, as measured by the Allen Human Brain Atlas, in relation to QSM images of age-matched subjects. We performed multiple linear regressions between gene expression and the average QSM signal within 34 distinct deep grey nuclei regions. Our results show a positive correlation (p

Published

2024

2. Cortical timescales and the modular organization of structural and functional brain networks.

Author

Lurie, Daniel, Pappas, Ioannis, and DEsposito, Mark

Subjects

brain dynamics, community structure, fmri, functional connectivity, network topology, structural connectivity, timescale, Humans, Brain, Cerebral Cortex, Brain Mapping, Magnetic Resonance Imaging, Rest, Nerve Net

Abstract

Recent years have seen growing interest in characterizing the properties of regional brain dynamics and their relationship to other features of brain structure and function. In particular, multiple studies have observed regional differences in the timescale over which activity fluctuates during periods of quiet rest. In the cerebral cortex, these timescales have been associated with both local circuit properties as well as patterns of inter-regional connectivity, including the extent to which each region exhibits widespread connectivity to other brain areas. In the current study, we build on prior observations of an association between connectivity and dynamics in the cerebral cortex by investigating the relationship between BOLD fMRI timescales and the modular organization of structural and functional brain networks. We characterize network community structure across multiple scales and find that longer timescales are associated with greater within-community functional connectivity and diverse structural connectivity. We also replicate prior observations of a positive correlation between timescales and structural connectivity degree. Finally, we find evidence for preferential functional connectivity between cortical areas with similar timescales. We replicate these findings in an independent dataset. These results contribute to our understanding of functional brain organization and structure-function relationships in the human brain, and support the notion that regional differences in cortical dynamics may in part reflect the topological role of each region within macroscale brain networks.

Published

2024

3. The alterations of repetitive transcranial magnetic stimulation on the energy landscape of resting‐state networks differ across the human cortex.

Author

Fan, Liming, Su, Chunwang, Li, Youjun, Guo, Jinjia, Huang, Zi‐Gang, Zhang, Wenlong, Liu, Tian, and Wang, Jue

Subjects

*TRANSCRANIAL magnetic stimulation, *LARGE-scale brain networks, *CLINICAL neurosciences, *BRAIN mapping, *ENERGY levels (Quantum mechanics)

Abstract

Repetitive transcranial magnetic stimulation (rTMS) is a promising intervention tool for the noninvasive modulation of brain activity and behavior in neuroscience research and clinical settings. However, the resting‐state dynamic evolution of large‐scale functional brain networks following rTMS has rarely been investigated. Here, using resting‐state fMRI images collected from 23 healthy individuals before (baseline) and after 1 Hz rTMS of the left frontal (FRO) and occipital (OCC) lobes, we examined the different effects of rTMS on brain dynamics across the human cortex. By fitting a pairwise maximum entropy model (pMEM), we constructed an energy landscape for the baseline and poststimulus conditions by fitting a pMEM. We defined dominant brain states (local minima) in the energy landscape with synergistic activation and deactivation patterns of large‐scale functional networks. We calculated state dynamics including appearance probability, transitions and duration. The results showed that 1 Hz rTMS induced increased and decreased state probability, transitions and duration when delivered to the FRO and OCC targets, respectively. Most importantly, the shortest path and minimum cost between dominant brain states were altered after stimulation. The absolute sum of the costs from the source states to the destinations was lower after OCC stimulation than after FRO stimulation. In conclusion, our study characterized the dynamic trajectory of state transitions in the energy landscape and suggested that local rTMS can induce significant dynamic perturbation involving stimulated and distant functional networks, which aligns with the modern view of the dynamic and complex brain. Our results suggest low‐dimensional mapping of rTMS‐induced brain adaption, which will contribute to a broader and more effective application of rTMS in clinical settings. [ABSTRACT FROM AUTHOR]

Published

2024

4. Generalized models for estimating cerebral lateralisation of young children using functional transcranial Doppler ultrasound.

Author

Quin‐Conroy, Josephine E., Thompson, Paul A., Bayliss, Donna M., and Badcock, Nicholas A.

Subjects

*TRANSCRANIAL Doppler ultrasonography, *COMMON misconceptions, *BRAIN mapping, *LATERAL dominance, *ADULTS

Abstract

Thompson et al., 2023 (Generalized models for quantifying laterality using functional transcranial Doppler ultrasound. Human Brain Mapping, 44(1), 35–48) introduced generalised model‐based analysis methods for determining cerebral lateralisation from functional transcranial Doppler ultrasound (fTCD) data which substantially decreased the uncertainty of individual lateralisation estimates across several large adult samples. We aimed to assess the suitability of these methods for increasing precision in lateralisation estimates for child fTCD data. We applied these methods to adult fTCD data to establish the validity of two child‐friendly language and visuospatial tasks. We also applied the methods to fTCD data from 4‐ to 7‐year‐old children. For both samples, the laterality estimates from the complex generalised additive model (GAM) approach correlated strongly with the traditional methods while also decreasing individual standard errors compared to the popular period‐of‐interest averaging method. We recommend future research using fTCD with young children consider using GAMs to reduce the noise in their LI estimates. [ABSTRACT FROM AUTHOR]

Published

2024

5. Characterizing systemic physiological effects on the blood oxygen level dependent signal of resting‐state fMRI in time‐frequency space using wavelets

Author

Lee, Quimby N, Chen, Jingyuan E, Wheeler, Gregory J, and Fan, Audrey P

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Clinical Research, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Humans, Magnetic Resonance Imaging, Oxygen Saturation, Brain, Brain Mapping, Connectome, Respiration, heart rate variability, human connectome project, respiration volume per time, resting state networks, resting-state fMRI, wavelet transform coherence, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Systemic physiological dynamics, such as heart rate variability (HRV) and respiration volume per time (RVT), are known to account for significant variance in the blood oxygen level dependent (BOLD) signal of resting-state functional magnetic resonance imaging (rsfMRI). However, synchrony between these cardiorespiratory changes and the BOLD signal could be due to neuronal (i.e., autonomic activity inducing changes in heart rate and respiration) or vascular (i.e., cardiorespiratory activity facilitating hemodynamic changes and thus the BOLD signal) effects and the contributions of these effects may differ spatially, temporally, and spectrally. In this study, we characterize these brain-body dynamics using a wavelet analysis in rapidly sampled rsfMRI data with simultaneous pulse oximetry and respiratory monitoring of the Human Connectome Project. Our time-frequency analysis across resting-state networks (RSNs) revealed differences in the coherence of the BOLD signal and heartbeat interval (HBI)/RVT dynamics across frequencies, with unique profiles per network. Somatomotor (SMN), visual (VN), and salience (VAN) networks demonstrated the greatest synchrony with both systemic physiological signals when compared to other networks; however, significant coherence was observed in all RSNs regardless of direct autonomic involvement. Our phase analysis revealed distinct frequency profiles of percentage of time with significant coherence between BOLD and systemic physiological signals for different phase offsets across RSNs, suggesting that the phase offset and temporal order of signals varies by frequency. Lastly, our analysis of temporal variability of coherence provides insight on potential influence of autonomic state on brain-body communication. Overall, the novel wavelet analysis enables an efficient characterization of the dynamic relationship between cardiorespiratory activity and the BOLD signal in spatial, temporal, and spectral dimensions to inform our understanding of autonomic states and improve our interpretation of the BOLD signal.

Published

2023

6. EEG microstates in early-to-middle childhood show associations with age, biological sex, and alpha power.

Author

Hill, Aron, Bailey, Neil, Zomorrodi, Reza, Kirkovski, Melissa, Das, Sushmit, Lum, Jarrad, Enticott, Peter, and Hadas, Itay

Subjects

EEG, age, alpha power, biological sex, brain networks, microstates, neurodevelopment, neuroimaging, Adult, Humans, Child, Brain, Electroencephalography, Brain Mapping, Eye, Linear Models

Abstract

Electroencephalographic (EEG) microstates can provide a unique window into the temporal dynamics of large-scale brain networks across brief (millisecond) timescales. Here, we analysed fundamental temporal features of microstates extracted from the broadband EEG signal in a large (N = 139) cohort of children spanning early-to-middle childhood (4-12 years of age). Linear regression models were used to examine if participants age and biological sex could predict the temporal parameters GEV, duration, coverage, and occurrence, for five microstate classes (A-E) across both eyes-closed and eyes-open resting-state recordings. We further explored associations between these microstate parameters and posterior alpha power after removal of the 1/f-like aperiodic signal. The microstates obtained from our neurodevelopmental EEG recordings broadly replicated the four canonical microstate classes (A to D) frequently reported in adults, with the addition of the more recently established microstate class E. Biological sex served as a significant predictor in the regression models for four of the five microstate classes (A, C, D, and E). In addition, duration and occurrence for microstate E were both found to be positively associated with age for the eyes-open recordings, while the temporal parameters of microstates C and E both exhibited associations with alpha band spectral power. Together, these findings highlight the influence of age and sex on large-scale functional brain networks during early-to-middle childhood, extending understanding of neural dynamics across this important period for brain development.

Published

2023

7. Identifying canonical and replicable multi‐scale intrinsic connectivity networks in 100k+ resting‐state fMRI datasets

Author

Iraji, A, Fu, Z, Faghiri, A, Duda, M, Chen, J, Rachakonda, S, DeRamus, T, Kochunov, P, Adhikari, BM, Belger, A, Ford, JM, Mathalon, DH, Pearlson, GD, Potkin, SG, Preda, A, Turner, JA, van Erp, TGM, Bustillo, JR, Yang, K, Ishizuka, K, Faria, A, Sawa, A, Hutchison, K, Osuch, EA, Theberge, J, Abbott, C, Mueller, BA, Zhi, D, Zhuo, C, Liu, S, Xu, Y, Salman, M, Liu, J, Du, Y, Sui, J, Adali, T, and Calhoun, VD

Subjects

Biomedical and Clinical Sciences, Biological Psychology, Cognitive and Computational Psychology, Neurosciences, Psychology, Bioengineering, Clinical Research, Neurological, Humans, Brain Mapping, Magnetic Resonance Imaging, Reproducibility of Results, Nerve Net, Brain, functional connectivity, functional templates, independent component analysis, intrinsic connectivity networks, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Despite the known benefits of data-driven approaches, the lack of approaches for identifying functional neuroimaging patterns that capture both individual variations and inter-subject correspondence limits the clinical utility of rsfMRI and its application to single-subject analyses. Here, using rsfMRI data from over 100k individuals across private and public datasets, we identify replicable multi-spatial-scale canonical intrinsic connectivity network (ICN) templates via the use of multi-model-order independent component analysis (ICA). We also study the feasibility of estimating subject-specific ICNs via spatially constrained ICA. The results show that the subject-level ICN estimations vary as a function of the ICN itself, the data length, and the spatial resolution. In general, large-scale ICNs require less data to achieve specific levels of (within- and between-subject) spatial similarity with their templates. Importantly, increasing data length can reduce an ICN's subject-level specificity, suggesting longer scans may not always be desirable. We also find a positive linear relationship between data length and spatial smoothness (possibly due to averaging over intrinsic dynamics), suggesting studies examining optimized data length should consider spatial smoothness. Finally, consistency in spatial similarity between ICNs estimated using the full data and subsets across different data lengths suggests lower within-subject spatial similarity in shorter data is not wholly defined by lower reliability in ICN estimates, but may be an indication of meaningful brain dynamics which average out as data length increases.

Published

2023

8. Utilizing connectome fingerprinting functional MRI models for motor activity prediction in presurgical planning: A feasibility study.

Author

Tripathi, Vaibhav, Rigolo, Laura, Bracken, Bethany K., Galvin, Colin P., Golby, Alexandra J., Tie, Yanmei, and Somers, David C.

Subjects

*FUNCTIONAL magnetic resonance imaging, *LARGE-scale brain networks, *BRAIN tumors, *VISUAL cortex, *FEASIBILITY studies, *BRAIN mapping

Abstract

Presurgical planning prior to brain tumor resection is critical for the preservation of neurologic function post‐operatively. Neurosurgeons increasingly use advanced brain mapping techniques pre‐ and intra‐operatively to delineate brain regions which are "eloquent" and should be spared during resection. Functional MRI (fMRI) has emerged as a commonly used non‐invasive modality for individual patient mapping of critical cortical regions such as motor, language, and visual cortices. To map motor function, patients are scanned using fMRI while they perform various motor tasks to identify brain networks critical for motor performance, but it may be difficult for some patients to perform tasks in the scanner due to pre‐existing deficits. Connectome fingerprinting (CF) is a machine‐learning approach that learns associations between resting‐state functional networks of a brain region and the activations in the region for specific tasks; once a CF model is constructed, individualized predictions of task activation can be generated from resting‐state data. Here we utilized CF to train models on high‐quality data from 208 subjects in the Human Connectome Project (HCP) and used this to predict task activations in our cohort of healthy control subjects (n = 15) and presurgical patients (n = 16) using resting‐state fMRI (rs‐fMRI) data. The prediction quality was validated with task fMRI data in the healthy controls and patients. We found that the task predictions for motor areas are on par with actual task activations in most healthy subjects (model accuracy around 90%–100% of task stability) and some patients suggesting the CF models can be reliably substituted where task data is either not possible to collect or hard for subjects to perform. We were also able to make robust predictions in cases in which there were no task‐related activations elicited. The findings demonstrate the utility of the CF approach for predicting activations in out‐of‐sample subjects, across sites and scanners, and in patient populations. This work supports the feasibility of the application of CF models to presurgical planning, while also revealing challenges to be addressed in future developments. Practitioner Points: Precision motor network prediction using connectome fingerprinting.Carefully trained models' performance limited by stability of task‐fMRI data.Successful cross‐scanner predictions and motor network mapping in patients with tumor. [ABSTRACT FROM AUTHOR]

Published

2024

9. Identifying the neural correlates of anticipatory postural control: A novel fMRI paradigm.

Author

Smith, Jo, Tain, Rongwen, Sharp, Kelli, Glynn, Laura, Van Dillen, Linda, Henslee, Korinne, Jacobs, Jesse, and Cramer, Steven

Subjects

functional MRI, movement, neuroimaging, postural control, sensorimotor, trunk, Humans, Magnetic Resonance Imaging, Brain, Brain Mapping, Cerebellum, Leg

Abstract

Altered postural control in the trunk/hip musculature is a characteristic of multiple neurological and musculoskeletal conditions. Previously it was not possible to determine if altered cortical and subcortical sensorimotor brain activation underlies impairments in postural control. This study used a novel fMRI-compatible paradigm to identify the brain activation associated with postural control in the trunk and hip musculature. BOLD fMRI imaging was conducted as participants performed two versions of a lower limb task involving lifting the left leg to touch the foot to a target. For the supported leg raise (SLR) the leg is raised from the knee while the thigh remains supported. For the unsupported leg raise (ULR) the leg is raised from the hip, requiring postural muscle activation in the abdominal/hip extensor musculature. Significant brain activation during the SLR task occurred predominantly in the right primary and secondary sensorimotor cortical regions. Brain activation during the ULR task occurred bilaterally in the primary and secondary sensorimotor cortical regions, as well as cerebellum and putamen. In comparison with the SLR, the ULR was associated with significantly greater activation in the right premotor/SMA, left primary motor and cingulate cortices, primary somatosensory cortex, supramarginal gyrus/parietal operculum, superior parietal lobule, cerebellar vermis, and cerebellar hemispheres. Cortical and subcortical regions activated during the ULR, but not during the SLR, were consistent with the planning, and execution of a task involving multisegmental, bilateral postural control. Future studies using this paradigm will determine mechanisms underlying impaired postural control in patients with neurological and musculoskeletal dysfunction.

Published

2023

10. Direct localization and delineation of human pedunculopontine nucleus based on a self‐supervised magnetic resonance image super‐resolution method

Author

Li, Jun, Guan, Xiaojun, Wu, Qing, He, Chenyu, Zhang, Weimin, Lin, Xiyue, Liu, Chunlei, Wei, Hongjiang, Xu, Xiaojun, and Zhang, Yuyao

Subjects

Neurosciences, Biomedical Imaging, Clinical Research, Bioengineering, Neurological, Young Adult, Humans, Magnetic Resonance Imaging, Pedunculopontine Tegmental Nucleus, Brain, Brain Mapping, Deep Brain Stimulation, brainstem, deep brain stimulation, direct targeting, implicit representation, pedunculopontine nucleus, quantitative susceptibility mapping, self-supervised image super-resolution, Cognitive Sciences, Experimental Psychology

Abstract

The pedunculopontine nucleus (PPN) is a small brainstem structure and has attracted attention as a potentially effective deep brain stimulation (DBS) target for the treatment of Parkinson's disease (PD). However, the in vivo location of PPN remains poorly described and barely visible on conventional structural magnetic resonance (MR) images due to a lack of high spatial resolution and tissue contrast. This study aims to delineate the PPN on a high-resolution (HR) atlas and investigate the visibility of the PPN in individual quantitative susceptibility mapping (QSM) images. We combine a recently constructed Montreal Neurological Institute (MNI) space unbiased QSM atlas (MuSus-100), with an implicit representation-based self-supervised image super-resolution (SR) technique to achieve an atlas with improved spatial resolution. Then guided by a myelin staining histology human brain atlas, we localize and delineate PPN on the atlas with improved resolution. Furthermore, we examine the feasibility of directly identifying the approximate PPN location on the 3.0-T individual QSM MR images. The proposed SR network produces atlas images with four times the higher spatial resolution (from 1 to 0.25 mm isotropic) without a training dataset. The SR process also reduces artifacts and keeps superb image contrast for further delineating small deep brain nuclei, such as PPN. Using the myelin staining histological atlas as guidance, we first identify and annotate the location of PPN on the T1-weighted (T1w)-QSM hybrid MR atlas with improved resolution in the MNI space. Then, we relocate and validate that the optimal targeting site for PPN-DBS is at the middle-to-caudal part of PPN on our atlas. Furthermore, we confirm that the PPN region can be identified in a set of individual QSM images of 10 patients with PD and 10 healthy young adults. The contrast ratios of the PPN to its adjacent structure, namely the medial lemniscus, on images of different modalities indicate that QSM substantially improves the visibility of the PPN both in the atlas and individual images. Our findings indicate that the proposed SR network is an efficient tool for small-size brain nucleus identification. HR QSM is promising for improving the visibility of the PPN. The PPN can be directly identified on the individual QSM images acquired at the 3.0-T MR scanners, facilitating a direct targeting of PPN for DBS surgery.

Published

2023

11. Reliability and clinical utility of spatially constrained estimates of intrinsic functional networks from very short fMRI scans.

Author

Duda, Marlena, Iraji, Armin, Ford, Judith M, Lim, Kelvin O, Mathalon, Daniel H, Mueller, Bryon A, Potkin, Steven G, Preda, Adrian, Van Erp, Theo GM, and Calhoun, Vince D

Subjects

Brain, Humans, Magnetic Resonance Imaging, Brain Mapping, Reproducibility of Results, Mood Disorders, Neuroimaging, functional network connectivity, intrinsic connectivity networks, resting-state fMRI, schizophrenia, spatially constrained independent components analysis, Clinical Research, Neurosciences, Biomedical Imaging, Mental Health, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Cognitive Sciences, Experimental Psychology

Abstract

Resting-state functional network connectivity (rsFNC) has shown utility for identifying characteristic functional brain patterns in individuals with psychiatric and mood disorders, providing a promising avenue for biomarker development. However, several factors have precluded widespread clinical adoption of rsFNC diagnostics, namely a lack of standardized approaches for capturing comparable and reproducible imaging markers across individuals, as well as the disagreement on the amount of data required to robustly detect intrinsic connectivity networks (ICNs) and diagnostically relevant patterns of rsFNC at the individual subject level. Recently, spatially constrained independent component analysis (scICA) has been proposed as an automated method for extracting ICNs standardized to a chosen network template while still preserving individual variation. Leveraging the scICA methodology, which solves the former challenge of standardized neuroimaging markers, we investigate the latter challenge of identifying a minimally sufficient data length for clinical applications of resting-state fMRI (rsfMRI). Using a dataset containing rsfMRI scans of individuals with schizophrenia and controls (M = 310) as well as simulated rsfMRI, we evaluated the robustness of ICN and rsFNC estimates at both the subject- and group-level, as well as the performance of diagnostic classification, with respect to the length of the rsfMRI time course. We found individual estimates of ICNs and rsFNC from the full-length (5 min) reference time course were sufficiently approximated with just 3-3.5 min of data (r = 0.85, 0.88, respectively), and significant differences in group-average rsFNC could be sufficiently approximated with even less data, just 2 min (r = 0.86). These results from the shorter clinical data were largely consistent with the results from validation experiments using longer time series from both simulated (30 min) and real-world (14 min) datasets, in which estimates of subject-level FNC were reliably estimated with 3-5 min of data. Moreover, in the real-world data we found rsFNC and ICN estimates generated across the full range of data lengths (0.5-14 min) more reliably matched those generated from the first 5 min of scan time than those generated from the last 5 min, suggesting increased influence of "late scan" noise factors such as fatigue or drowsiness may limit the reliability of FNC from data collected after 10+ min of scan time, further supporting the notion of shorter scans. Lastly, a diagnostic classification model trained on just 2 min of data retained 97%-98% classification accuracy relative to that of the full-length reference model. Our results suggest that, when decomposed with scICA, rsfMRI scans of just 2-5 min show good clinical utility without significant loss of individual FNC information of longer scan lengths.

Published

2023

12. Evaluating the reliability, validity, and utility of overlapping networks: Implications for network theories of cognition

Author

Cookson, Savannah L and D'Esposito, Mark

Subjects

Cognitive and Computational Psychology, Psychology, Neurosciences, Brain Disorders, Humans, Reproducibility of Results, Magnetic Resonance Imaging, Cognition, Brain, Brain Mapping, Nerve Net, clustering, cognitive control, functional connectivity, multiple-network membership, network neuroscience, overlapping networks, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Brain network definitions typically assume nonoverlap or minimal overlap, ignoring regions' connections to multiple networks. However, new methods are emerging that emphasize network overlap. Here, we investigated the reliability and validity of one assignment method, the mixed membership algorithm, and explored its potential utility for identifying gaps in existing network models of cognition. We first assessed between-sample reliability of overlapping assignments with a split-half design; a bootstrapped Dice similarity analysis demonstrated good agreement between the networks from the two subgroups. Next, we assessed whether overlapping networks captured expected nonoverlapping topographies; overlapping networks captured portions of one to three nonoverlapping topographies, which aligned with canonical network definitions. Following this, a relative entropy analysis showed that a majority of regions participated in more than one network, as is seen biologically, and many regions did not show preferential connection to any one network. Finally, we explored overlapping network membership in regions of the dual-networks model of cognitive control, showing that almost every region was a member of multiple networks. Thus, the mixed membership algorithm produces consistent and biologically plausible networks, which presumably will allow for the development of more complete network models of cognition.

Published

2023

13. Mapping Interictal activity in epilepsy using a hidden Markov model: A magnetoencephalography study.

Author

Seedat, Zelekha, Rier, Lukas, Gascoyne, Lauren, Cook, Harry, Woolrich, Mark, Quinn, Andrew, Roberts, Timothy, Furlong, Paul, Armstrong, Caren, St Pier, Kelly, Mullinger, Karen, Marsh, Eric, Brookes, Matthew, and Gaetz, William

Subjects

epilepsy, hidden Markov model, interictal activity, magnetoencephalography, Humans, Child, Magnetoencephalography, Epilepsy, Drug Resistant Epilepsy, Philadelphia, Brain Mapping, Electroencephalography

Abstract

Epilepsy is a highly heterogeneous neurological disorder with variable etiology, manifestation, and response to treatment. It is imperative that new models of epileptiform brain activity account for this variability, to identify individual needs and allow clinicians to curate personalized care. Here, we use a hidden Markov model (HMM) to create a unique statistical model of interictal brain activity for 10 pediatric patients. We use magnetoencephalography (MEG) data acquired as part of standard clinical care for patients at the Childrens Hospital of Philadelphia. These data are routinely analyzed using excess kurtosis mapping (EKM); however, as cases become more complex (extreme multifocal and/or polymorphic activity), they become harder to interpret with EKM. We assessed the performance of the HMM against EKM for three patient groups, with increasingly complicated presentation. The difference in localization of epileptogenic foci for the two methods was 7 ± 2 mm (mean ± SD over all 10 patients); and 94% ± 13% of EKM temporal markers were matched by an HMM state visit. The HMM localizes epileptogenic areas (in agreement with EKM) and provides additional information about the relationship between those areas. A key advantage over current methods is that the HMM is a data-driven model, so the output is tuned to each individual. Finally, the model output is intuitive, allowing a user (clinician) to review the result and manually select the HMM epileptiform state, offering multiple advantages over previous methods and allowing for broader implementation of MEG epileptiform analysis in surgical decision-making for patients with intractable epilepsy.

Published

2023

14. In vivo disentanglement of diffusion frequency‐dependence, tensor shape, and relaxation using multidimensional MRI.

Author

Johnson, Jessica T. E., Irfanoglu, M. Okan, Manninen, Eppu, Ross, Thomas J., Yang, Yihong, Laun, Frederik B., Martin, Jan, Topgaard, Daniel, and Benjamini, Dan

Subjects

*DIFFUSION magnetic resonance imaging, *MAGNETIC resonance imaging, *DIAGNOSTIC imaging, *TISSUES, *BRAIN mapping

Abstract

Diffusion MRI with free gradient waveforms, combined with simultaneous relaxation encoding, referred to as multidimensional MRI (MD‐MRI), offers microstructural specificity in complex biological tissue. This approach delivers intravoxel information about the microstructure, local chemical composition, and importantly, how these properties are coupled within heterogeneous tissue containing multiple microenvironments. Recent theoretical advances incorporated diffusion time dependency and integrated MD‐MRI with concepts from oscillating gradients. This framework probes the diffusion frequency, ω$$ \omega $$, in addition to the diffusion tensor, D$$ \mathbf{D} $$, and relaxation, R1$$ {R}_1 $$, R2$$ {R}_2 $$, correlations. A Dω−R1−R2$$ \mathbf{D}\left(\omega \right)-{R}_1-{R}_2 $$ clinical imaging protocol was then introduced, with limited brain coverage and 3 mm3 voxel size, which hinder brain segmentation and future cohort studies. In this study, we introduce an efficient, sparse in vivo MD‐MRI acquisition protocol providing whole brain coverage at 2 mm3 voxel size. We demonstrate its feasibility and robustness using a well‐defined phantom and repeated scans of five healthy individuals. Additionally, we test different denoising strategies to address the sparse nature of this protocol, and show that efficient MD‐MRI encoding design demands a nuanced denoising approach. The MD‐MRI framework provides rich information that allows resolving the diffusion frequency dependence into intravoxel components based on their Dω−R1−R2$$ \mathbf{D}\left(\omega \right)-{R}_1-{R}_2 $$ distribution, enabling the creation of microstructure‐specific maps in the human brain. Our results encourage the broader adoption and use of this new imaging approach for characterizing healthy and pathological tissues. [ABSTRACT FROM AUTHOR]

Published

2024

15. Diffusion‐tensor‐imaging 1‐year‐old and 2‐year‐old infant brain atlases with comprehensive gray and white matter labels.

Author

Song, Limei, Peng, Yun, Ouyang, Minhui, Peng, Qinmu, Feng, Lei, Sotardi, Susan, Yu, Qinlin, Kang, Huiying, Sindabizera, Kay L., Liu, Shuwei, and Huang, Hao

Subjects

*GRAY matter (Nerve tissue), *WHITE matter (Nerve tissue), *INFANTS, *DIFFUSION tensor imaging, *NEURAL development

Abstract

Human infancy is marked by fastest postnatal brain structural changes. It also coincides with the onset of many neurodevelopmental disorders. Atlas‐based automated structure labeling has been widely used for analyzing various neuroimaging data. However, the relatively large and nonlinear neuroanatomical differences between infant and adult brains can lead to significant offsets of the labeled structures in infant brains when adult brain atlas is used. Age‐specific 1‐ and 2‐year‐old brain atlases covering all major gray and white matter (GM and WM) structures with diffusion tensor imaging (DTI) and structural MRI are critical for precision medicine for infant population yet have not been established. In this study, high‐quality DTI and structural MRI data were obtained from 50 healthy children to build up three‐dimensional age‐specific 1‐ and 2‐year‐old brain templates and atlases. Age‐specific templates include a single‐subject template as well as two population‐averaged templates from linear and nonlinear transformation, respectively. Each age‐specific atlas consists of 124 comprehensively labeled major GM and WM structures, including 52 cerebral cortical, 10 deep GM, 40 WM, and 22 brainstem and cerebellar structures. When combined with appropriate registration methods, the established atlases can be used for highly accurate automatic labeling of any given infant brain MRI. We demonstrated that one can automatically and effectively delineate deep WM microstructural development from 3 to 38 months by using these age‐specific atlases. These established 1‐ and 2‐year‐old infant brain DTI atlases can advance our understanding of typical brain development and serve as clinical anatomical references for brain disorders during infancy. [ABSTRACT FROM AUTHOR]

Published

2024

16. Mapping brain function in adults and young children during naturalistic viewing with high‐density diffuse optical tomography.

Author

Tripathy, Kalyan, Fogarty, Morgan, Svoboda, Alexandra M., Schroeder, Mariel L., Rafferty, Sean M., Richter, Edward J., Tracy, Christopher, Mansfield, Patricia K., Booth, Madison, Fishell, Andrew K., Sherafati, Arefeh, Markow, Zachary E., Wheelock, Muriah D., Arbeláez, Ana María, Schlaggar, Bradley L., Smyser, Christopher D., Eggebrecht, Adam T., and Culver, Joseph P.

Subjects

*OPTICAL tomography, *BRAIN mapping, *NEAR infrared spectroscopy, *CHILD patients, *NEURAL development, *VISUAL fields, *VECTION

Abstract

Human studies of early brain development have been limited by extant neuroimaging methods. MRI scanners present logistical challenges for imaging young children, while alternative modalities like functional near‐infrared spectroscopy have traditionally been limited by image quality due to sparse sampling. In addition, conventional tasks for brain mapping elicit low task engagement, high head motion, and considerable participant attrition in pediatric populations. As a result, typical and atypical developmental trajectories of processes such as language acquisition remain understudied during sensitive periods over the first years of life. We evaluate high‐density diffuse optical tomography (HD‐DOT) imaging combined with movie stimuli for high resolution optical neuroimaging in awake children ranging from 1 to 7 years of age. We built an HD‐DOT system with design features geared towards enhancing both image quality and child comfort. Furthermore, we characterized a library of animated movie clips as a stimulus set for brain mapping and we optimized associated data analysis pipelines. Together, these tools could map cortical responses to movies and contained features such as speech in both adults and awake young children. This study lays the groundwork for future research to investigate response variability in larger pediatric samples and atypical trajectories of early brain development in clinical populations. [ABSTRACT FROM AUTHOR]

Published

2024

17. Neural signatures of shared subjective affective engagement and disengagement during movie viewing.

Author

Nanni‐Zepeda, Melanni, DeGutis, Joseph, Wu, Charley, Rothlein, David, Fan, Yan, Grimm, Simone, Walter, Martin, Esterman, Michael, and Zuberer, Agnieszka

Subjects

*FUNCTIONAL magnetic resonance imaging, *DEFAULT mode network, *BRAIN mapping, *PREFRONTAL cortex, *SIMILARITY (Psychology), *EMOTION regulation

Abstract

When watching a negative emotional movie, we differ from person to person in the ease with which we engage and the difficulty with which we disengage throughout a temporally evolving narrative. We investigated neural responses of emotional processing, by considering inter‐individual synchronization in subjective emotional engagement and disengagement. The neural underpinnings of these shared responses are ideally studied in naturalistic scenarios like movie viewing, wherein individuals emotionally engage and disengage at their own time and pace throughout the course of a narrative. Despite the rich data that naturalistic designs can bring to the study, there is a challenge in determining time‐resolved behavioral markers of subjective engagement and disengagement and their underlying neural responses. We used a within‐subject cross‐over design instructing 22 subjects to watch clips of either neutral or sad content while undergoing functional magnetic resonance imaging (fMRI). Participants watched the same movies a second time while continuously annotating the perceived emotional intensity, thus enabling the mapping of brain activity and emotional experience. Our analyses revealed that between‐participant similarity in waxing (engagement) and waning (disengagement) of emotional intensity was directly related to the between‐participant similarity in spatiotemporal patterns of brain activation during the movie(s). Similar patterns of engagement reflected common activation in the bilateral ventromedial prefrontal cortex, regions often involved in self‐referenced evaluation and generation of negative emotions. Similar patterns of disengagement reflected common activation in central executive and default mode network regions often involved in top‐down emotion regulation. Together this work helps to better understand cognitive and neural mechanisms underpinning engagement and disengagement from emotionally evocative narratives. [ABSTRACT FROM AUTHOR]

Published

2024

18. Nonlinear functional network connectivity in resting functional magnetic resonance imaging data

Author

Motlaghian, Sara M, Belger, Aysenil, Bustillo, Juan R, Ford, Judith M, Iraji, Armin, Lim, Kelvin, Mathalon, Daniel H, Mueller, Bryon A, O'Leary, Daniel, Pearlson, Godfrey, Potkin, Steven G, Preda, Adrian, Erp, Theo GM, and Calhoun, Vince D

Subjects

Brain Disorders, Neurosciences, Schizophrenia, Mental Health, Mental health, Neurological, Brain, Brain Mapping, Humans, Magnetic Resonance Imaging, Rest, Visual Cortex, functional network connectivity, mutual information, nonlinear functional network connectivity, time courses, Cognitive Sciences, Experimental Psychology

Abstract

In this work, we focus on explicitly nonlinear relationships in functional networks. We introduce a technique using normalized mutual information (NMI) that calculates the nonlinear relationship between different brain regions. We demonstrate our proposed approach using simulated data and then apply it to a dataset previously studied by Damaraju et al. This resting-state fMRI data included 151 schizophrenia patients and 163 age- and gender-matched healthy controls. We first decomposed these data using group independent component analysis (ICA) and yielded 47 functionally relevant intrinsic connectivity networks. Our analysis showed a modularized nonlinear relationship among brain functional networks that was particularly noticeable in the sensory and visual cortex. Interestingly, the modularity appears both meaningful and distinct from that revealed by the linear approach. Group analysis identified significant differences in explicitly nonlinear functional network connectivity (FNC) between schizophrenia patients and healthy controls, particularly in the visual cortex, with controls showing more nonlinearity (i.e., higher normalized mutual information between time courses with linear relationships removed) in most cases. Certain domains, including subcortical and auditory, showed relatively less nonlinear FNC (i.e., lower normalized mutual information), whereas links between the visual and other domains showed evidence of substantial nonlinear and modular properties. Overall, these results suggest that quantifying nonlinear dependencies of functional connectivity may provide a complementary and potentially important tool for studying brain function by exposing relevant variation that is typically ignored. Beyond this, we propose a method that captures both linear and nonlinear effects in a "boosted" approach. This method increases the sensitivity to group differences compared to the standard linear approach, at the cost of being unable to separate linear and nonlinear effects.

Published

2022

19. A new multimodality fusion classification approach to explore the uniqueness of schizophrenia and autism spectrum disorder

Author

Du, Yuhui, He, Xingyu, Kochunov, Peter, Pearlson, Godfrey, Hong, L Elliot, Erp, Theo GM, Belger, Aysenil, and Calhoun, Vince D

Subjects

Pediatric, Autism, Clinical Research, Serious Mental Illness, Neurosciences, Intellectual and Developmental Disabilities (IDD), Mental Health, Brain Disorders, Schizophrenia, Aetiology, 2.1 Biological and endogenous factors, Mental health, Autism Spectrum Disorder, Brain, Brain Mapping, Humans, Magnetic Resonance Imaging, Multimodal Imaging, autism spectrum disorder, classification, functional magnetic resonance imaging, fusion, schizophrenia, structural magnetic resonance imaging, Cognitive Sciences, Experimental Psychology

Abstract

Schizophrenia (SZ) and autism spectrum disorder (ASD) sharing overlapping symptoms have a long history of diagnostic confusion. It is unclear what their differences at a brain level are. Here, we propose a multimodality fusion classification approach to investigate their divergence in brain function and structure. Using brain functional network connectivity (FNC) calculated from resting-state fMRI data and gray matter volume (GMV) estimated from sMRI data, we classify the two disorders using the main data (335 SZ and 380 ASD patients) via an unbiased 10-fold cross-validation pipeline, and also validate the classification generalization ability on an independent cohort (120 SZ and 349 ASD patients). The classification accuracy reached up to 83.08% for the testing data and 72.10% for the independent data, significantly better than the results from using the single-modality features. The discriminative FNCs that were automatically selected primarily involved the sub-cortical, default mode, and visual domains. Interestingly, all discriminative FNCs relating to the default mode network showed an intermediate strength in healthy controls (HCs) between SZ and ASD patients. Their GMV differences were mainly driven by the frontal gyrus, temporal gyrus, and insula. Regarding these regions, the mean GMV of HC fell intermediate between that of SZ and ASD, and ASD showed the highest GMV. The middle frontal gyrus was associated with both functional and structural differences. In summary, our work reveals the unique neuroimaging characteristics of SZ and ASD that can achieve high and generalizable classification accuracy, supporting their potential as disorder-specific neural substrates of the two entwined disorders.

Published

2022

20. Cortical mapping of callosal connections in healthy young adults.

Author

Xiong, Yirong, Yang, Liyuan, Wang, Changtong, Zhao, Chenxi, Luo, Junhao, Wu, Di, Ouyang, Yiping, de Thiebaut de Schotten, Michel, and Gong, Gaolang

Subjects

*YOUNG adults, *BRAIN mapping, *CORPUS callosum, *CEREBRAL cortex, *TOPOGRAPHIC maps

Abstract

The corpus callosum (CC) is the principal white matter bundle supporting communication between the two brain hemispheres. Despite its importance, a comprehensive mapping of callosal connections is still lacking. Here, we constructed the first bidirectional population‐based callosal connectional atlas between the midsagittal section of the CC and the cerebral cortex of the human brain by means of diffusion‐weighted imaging tractography. The estimated connectional topographic maps within this atlas have the most fine‐grained spatial resolution, demonstrate histological validity, and were reproducible in two independent samples. This new resource, a complete and comprehensive atlas, will facilitate the investigation of interhemispheric communication and come with a user‐friendly companion online tool (CCmapping) for easy access and visualization of the atlas. [ABSTRACT FROM AUTHOR]

Published

2024

21. Deep learning‐based BMI inference from structural brain MRI reflects brain alterations following lifestyle intervention.

Author

Finkelstein, Ofek, Levakov, Gidon, Kaplan, Alon, Zelicha, Hila, Meir, Anat Yaskolka, Rinott, Ehud, Tsaban, Gal, Witte, Anja Veronica, Blüher, Matthias, Stumvoll, Michael, Shelef, Ilan, Shai, Iris, Riklin Raviv, Tammy, and Avidan, Galia

Subjects

*MAGNETIC resonance imaging, *ARTIFICIAL intelligence, *METABOLIC syndrome, *BRAIN mapping, *OBESITY complications

Abstract

Obesity is associated with negative effects on the brain. We exploit Artificial Intelligence (AI) tools to explore whether differences in clinical measurements following lifestyle interventions in overweight population could be reflected in brain morphology. In the DIRECT‐PLUS clinical trial, participants with criterion for metabolic syndrome underwent an 18‐month lifestyle intervention. Structural brain MRIs were acquired before and after the intervention. We utilized an ensemble learning framework to predict Body‐Mass Index (BMI) scores, which correspond to adiposity‐related clinical measurements from brain MRIs. We revealed that patient‐specific reduction in BMI predictions was associated with actual weight loss and was significantly higher in active diet groups compared to a control group. Moreover, explainable AI (XAI) maps highlighted brain regions contributing to BMI predictions that were distinct from regions associated with age prediction. Our DIRECT‐PLUS analysis results imply that predicted BMI and its reduction are unique neural biomarkers for obesity‐related brain modifications and weight loss. [ABSTRACT FROM AUTHOR]

Published

2024

22. Individual word representations dissociate from linguistic context along a cortical unimodal to heteromodal gradient.

Author

Eisenhauer, Susanne, Gonzalez Alam, Tirso Rene del Jesus, Cornelissen, Piers L., Smallwood, Jonathan, and Jefferies, Elizabeth

Subjects

*LINGUISTIC context, *NEUROLINGUISTICS, *FUNCTIONAL magnetic resonance imaging, *ORTHOGRAPHY & spelling, *BRAIN mapping, *WORD frequency

Abstract

Language comprehension involves multiple hierarchical processing stages across time, space, and levels of representation. When processing a word, the sensory input is transformed into increasingly abstract representations that need to be integrated with the linguistic context. Thus, language comprehension involves both input‐driven as well as context‐dependent processes. While neuroimaging research has traditionally focused on mapping individual brain regions to the distinct underlying processes, recent studies indicate that whole‐brain distributed patterns of cortical activation might be highly relevant for cognitive functions, including language. One such pattern, based on resting‐state connectivity, is the 'principal cortical gradient', which dissociates sensory from heteromodal brain regions. The present study investigated the extent to which this gradient provides an organizational principle underlying language function, using a multimodal neuroimaging dataset of functional magnetic resonance imaging (fMRI) and magnetoencephalography (MEG) recordings from 102 participants during sentence reading. We found that the brain response to individual representations of a word (word length, orthographic distance, and word frequency), which reflect visual; orthographic; and lexical properties, gradually increases towards the sensory end of the gradient. Although these properties showed opposite effect directions in fMRI and MEG, their association with the sensory end of the gradient was consistent across both neuroimaging modalities. In contrast, MEG revealed that properties reflecting a word's relation to its linguistic context (semantic similarity and position within the sentence) involve the heteromodal end of the gradient to a stronger extent. This dissociation between individual word and contextual properties was stable across earlier and later time windows during word presentation, indicating interactive processing of word representations and linguistic context at opposing ends of the principal gradient. To conclude, our findings indicate that the principal gradient underlies the organization of a range of linguistic representations while supporting a gradual distinction between context‐independent and context‐dependent representations. Furthermore, the gradient reveals convergent patterns across neuroimaging modalities (similar location along the gradient) in the presence of divergent responses (opposite effect directions). [ABSTRACT FROM AUTHOR]

Published

2024

23. Neural sensitivity to translational self‐ and object‐motion velocities.

Author

Sulpizio, Valentina, von Gal, Alessandro, Galati, Gaspare, Fattori, Patrizia, Galletti, Claudio, and Pitzalis, Sabrina

Subjects

*FUNCTIONAL magnetic resonance imaging, *CINGULATE cortex, *RELATIVE motion, *RELATIVE velocity, *OPTICAL flow

Abstract

The ability to detect and assess world‐relative object‐motion is a critical computation performed by the visual system. This computation, however, is greatly complicated by the observer's movements, which generate a global pattern of motion on the observer's retina. How the visual system implements this computation is poorly understood. Since we are potentially able to detect a moving object if its motion differs in velocity (or direction) from the expected optic flow generated by our own motion, here we manipulated the relative motion velocity between the observer and the object within a stationary scene as a strategy to test how the brain accomplishes object‐motion detection. Specifically, we tested the neural sensitivity of brain regions that are known to respond to egomotion‐compatible visual motion (i.e., egomotion areas: cingulate sulcus visual area, posterior cingulate sulcus area, posterior insular cortex [PIC], V6+, V3A, IPSmot/VIP, and MT+) to a combination of different velocities of visually induced translational self‐ and object‐motion within a virtual scene while participants were instructed to detect object‐motion. To this aim, we combined individual surface‐based brain mapping, task‐evoked activity by functional magnetic resonance imaging, and parametric and representational similarity analyses. We found that all the egomotion regions (except area PIC) responded to all the possible combinations of self‐ and object‐motion and were modulated by the self‐motion velocity. Interestingly, we found that, among all the egomotion areas, only MT+, V6+, and V3A were further modulated by object‐motion velocities, hence reflecting their possible role in discriminating between distinct velocities of self‐ and object‐motion. We suggest that these egomotion regions may be involved in the complex computation required for detecting scene‐relative object‐motion during self‐motion. [ABSTRACT FROM AUTHOR]

Published

2024

24. dcSBM: A federated constrained source‐based morphometry approach for multivariate brain structure mapping.

Author

Saha, Debbrata K., Silva, Rogers F., Baker, Bradley T., Saha, Rekha, and Calhoun, Vince D.

Subjects

*BRAIN anatomy, *BRAIN mapping, *MORPHOMETRICS, *INDEPENDENT component analysis, *MAGNETIC resonance imaging

Abstract

The examination of multivariate brain morphometry patterns has gained attention in recent years, especially for their powerful exploratory capabilities in the study of differences between patients and controls. Among the many existing methods and tools for the analysis of brain anatomy based on structural magnetic resonance imaging data, data‐driven source‐based morphometry (SBM) focuses on the exploratory detection of such patterns. Here, we implement a semi‐blind extension of SBM, called constrained source‐based morphometry (constrained SBM), which enables the extraction of maximally independent reference‐alike sources using the constrained independent component analysis (ICA) approach. To do this, we combine SBM with a set of reference components covering the full brain, derived from a large independent data set (UKBiobank), to provide a fully automated SBM framework. This also allows us to implement a federated version of constrained SBM (cSBM) to allow analysis of data that is not locally accessible. In our proposed decentralized constrained source‐based morphometry (dcSBM), the original data never leaves the local site. Each site operates constrained ICA on its private local data using a common distributed computation platform. Next, an aggregator/master node aggregates the results estimated from each local site and applies statistical analysis to estimate the significance of the sources. Finally, we utilize two additional multisite patient data sets to validate our model by comparing the resulting group difference estimates from both cSBM and dcSBM. [ABSTRACT FROM AUTHOR]

Published

2023

25. Retinotopic connectivity maps of human visual cortex with unconstrained eye movements.

Author

Tangtartharakul, Gene, Morgan, Catherine A., Rushton, Simon K., and Schwarzkopf, D. Samuel

Subjects

*VISUAL cortex, *EYE movements, *VISUAL fields, *MAPS, *FUNCTIONAL connectivity

Abstract

Human visual cortex contains topographic visual field maps whose organization can be revealed with retinotopic mapping. Unfortunately, constraints posed by standard mapping hinder its use in patients, atypical subject groups, and individuals at either end of the lifespan. This severely limits the conclusions we can draw about visual processing in such individuals. Here, we present a novel data‐driven method to estimate connective fields, resulting in fine‐grained maps of the functional connectivity between brain areas. We find that inhibitory connectivity fields accompany, and often surround facilitatory fields. The visual field extent of these inhibitory subfields falls off with cortical magnification. We further show that our method is robust to large eye movements and myopic defocus. Importantly, freed from the controlled stimulus conditions in standard mapping experiments, using entertaining stimuli and unconstrained eye movements our approach can generate retinotopic maps, including the periphery visual field hitherto only possible to map with special stimulus displays. Generally, our results show that the connective field method can gain knowledge about retinotopic architecture of visual cortex in patients and participants where this is at best difficult and confounded, if not impossible, with current methods. [ABSTRACT FROM AUTHOR]

Published

2023

26. Neural representations of the amount and the delay time of reward in intertemporal decision making

Author

Wang, Qiang, Wang, Yajie, Wang, Pinchun, Peng, Maomiao, Zhang, Manman, Zhu, Yuxuan, Wei, Shiyu, Chen, Chuansheng, Chen, Xiongying, Luo, Shan, and Bai, Xuejun

Subjects

Basic Behavioral and Social Science, Brain Disorders, Behavioral and Social Science, Neurosciences, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, Underpinning research, Mental health, Neurological, Adult, Brain Mapping, Delay Discounting, Dorsolateral Prefrontal Cortex, Female, Humans, Magnetic Resonance Imaging, Male, Prefrontal Cortex, Psychomotor Performance, Reward, Time Factors, Young Adult, dorsal medial prefrontal cortex, graph theory, intertemporal decision&#8208, making, multivariate pattern analysis, representational similarity analysis, intertemporal decision-making, Cognitive Sciences, Experimental Psychology

Abstract

Numerous studies have examined the neural substrates of intertemporal decision-making, but few have systematically investigated separate neural representations of the two attributes of future rewards (i.e., the amount of the reward and the delay time). More importantly, no study has used the novel analytical method of representational connectivity analysis (RCA) to map the two dimensions' functional brain networks at the level of multivariate neural representations. This study independently manipulated the amount and delay time of rewards during an intertemporal decision task. Both univariate and multivariate pattern analyses showed that brain activity in the dorsomedial prefrontal cortex (DMPFC) and lateral frontal pole cortex (LFPC) was modulated by the amount of rewards, whereas brain activity in the DMPFC and dorsolateral prefrontal cortex (DLPFC) was modulated by the length of delay. Moreover, representational similarity analysis (RSA) revealed that even for the regions of the DMPFC that overlapped between the two dimensions, they manifested distinct neural activity patterns. In terms of individual differences, those with large delay discounting rates (k) showed greater DMPFC and LFPC activity as the amount of rewards increased but showed lower DMPFC and DLPFC activity as the delay time increased. Lastly, RCA suggested that the topological metrics (i.e., global and local efficiency) of the functional connectome subserving the delay time dimension inversely predicted individual discounting rate. These findings provide novel insights into neural representations of the two attributes in intertemporal decisions, and offer a new approach to construct task-based functional brain networks whose topological properties are related to impulsivity.

Published

2021

27. Language distance in orthographic transparency affects cross‐language pattern similarity between native and non‐native languages

Author

Dong, Jie, Li, Aqian, Chen, Chuansheng, Qu, Jing, Jiang, Nan, Sun, Yue, Hu, Liyuan, and Mei, Leilei

Subjects

Biological Psychology, Cognitive and Computational Psychology, Psychology, Basic Behavioral and Social Science, Clinical Research, Neurosciences, Behavioral and Social Science, Neurological, Mental health, Quality Education, Adult, Brain Mapping, Cerebral Cortex, Female, Humans, Magnetic Resonance Imaging, Male, Multilingualism, Nerve Net, Pattern Recognition, Visual, Psycholinguistics, Reading, Young Adult, bilingual, fMRI, orthographic transparency, pattern similarity, word reading, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

How native and non-native languages are represented in the brain is one of the most important questions in neurolinguistics. Much research has found that the similarity in neural activity of native and non-native languages are influenced by factors such as age of acquisition, language proficiency, and language exposure in the non-native language. Nevertheless, it is still unclear how the similarity between native and non-native languages in orthographic transparency, a key factor that affects the cognitive and neural mechanisms of phonological access, modulates the cross-language similarity in neural activation and which brain regions show the modulatory effects of language distance in orthographic transparency. To address these questions, the present study used representational similarity analysis (RSA) to precisely estimate the neural pattern similarity between native language and two non-native languages in Uyghur-Chinese-English trilinguals, whose third language (i.e., English) was more similar to the native language (i.e., Uyghur) in orthography than to their second language (i.e., Chinese). Behavioral results revealed that subjects responded faster to words in the non-native language with more similar orthography to their native language in the word naming task. More importantly, RSA revealed greater neural pattern similarity between Uyghur and English than between Uyghur and Chinese in select brain areas for phonological processing, especially in the left hemisphere. Further analysis confirmed that those brain regions represented phonological information. These results provide direct neuroimaging evidence for the modulatory effect of language distance in orthographic transparency on cross-language pattern similarity between native and non-native languages during word reading.

Published

2021

28. An empirical comparison of univariate versus multivariate methods for the analysis of brain–behavior mapping

Author

Ivanova, Maria V, Herron, Timothy J, Dronkers, Nina F, and Baldo, Juliana V

Subjects

Biological Psychology, Psychology, Basic Behavioral and Social Science, Behavioral and Social Science, Neurosciences, Adult, Aged, Aged, 80 and over, Analysis of Variance, Brain Mapping, Cerebral Cortex, Computer Simulation, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Middle Aged, Nerve Net, Stroke, aphasia, brain&#8211, behavior relationships, language, lesion symptom mapping, multivariate, stroke, VLSM, brain-behavior relationships, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Lesion symptom mapping (LSM) tools are used on brain injury data to identify the neural structures critical for a given behavior or symptom. Univariate lesion symptom mapping (ULSM) methods provide statistical comparisons of behavioral test scores in patients with and without a lesion on a voxel by voxel basis. More recently, multivariate lesion symptom mapping (MLSM) methods have been developed that consider the effects of all lesioned voxels in one model simultaneously. In the current study, we provide a much-needed systematic comparison of several ULSM and MLSM methods, using both synthetic and real data to identify the potential strengths and weaknesses of both approaches. We tested the spatial precision of each LSM method for both single and dual (network type) anatomical target simulations across anatomical target location, sample size, noise level, and lesion smoothing. Additionally, we performed false positive simulations to identify the characteristics associated with each method's spurious findings. Simulations showed no clear superiority of either ULSM or MLSM methods overall, but rather highlighted specific advantages of different methods. No single method produced a thresholded LSM map that exclusively delineated brain regions associated with the target behavior. Thus, different LSM methods are indicated, depending on the particular study design, specific hypotheses, and sample size. Overall, we recommend the use of both ULSM and MLSM methods in tandem to enhance confidence in the results: Brain foci identified as significant across both types of methods are unlikely to be spurious and can be confidently reported as robust results.

Published

2021

29. Motion opponency examined throughout visual cortex with multivariate pattern analysis of fMRI data.

Author

Silva, Andrew, Thompson, Benjamin, and Liu, Zili

Subjects

MVPA, V3A, V5, hMT+, motion perception, noise reduction, Adult, Brain Mapping, Humans, Magnetic Resonance Imaging, Motion Perception, Multivariate Analysis, Support Vector Machine, Visual Cortex

Abstract

This study explores how the human brain solves the challenge of flicker noise in motion processing. Despite providing no useful directional motion information, flicker is common in the visual environment and exhibits omnidirectional motion energy which is processed by low-level motion detectors. Models of motion processing propose a mechanism called motion opponency that reduces flicker processing. Motion opponency involves the pooling of local motion signals to calculate an overall motion direction. A neural correlate of motion opponency has been observed in human area MT+/V5, whereby stimuli with perfectly balanced motion energy constructed from dots moving in counter-phase elicit a weaker response than nonbalanced (in-phase) motion stimuli. Building on this previous work, we used multivariate pattern analysis to examine whether the activation patterns elicited by motion opponent stimuli resemble that elicited by flicker noise across the human visual cortex. Robust multivariate signatures of opponency were observed in V5 and in V3A. Our results support the notion that V5 is centrally involved in motion opponency and in the reduction of flicker. Furthermore, these results demonstrate the utility of multivariate analysis methods in revealing the role of additional visual areas, such as V3A, in opponency and in motion processing more generally.

Published

2021

30. Striatonigrostriatal connectivity‐based cross‐species parcellation of human and macaque substantia nigra.

Author

Xia, Xiaoluan, Zeng, Xinglin, Gao, Fei, Hua, Lin, Huang, Shaohui, and Yuan, Zhen

Subjects

*SUBSTANTIA nigra, *MACAQUES, *RHESUS monkeys, *BRAIN mapping, *FUNCTIONAL connectivity

Abstract

Anatomical and functional heterogeneous substantia nigra (SN) has been extensively studied in humans and animals like rhesus monkeys given its crucial role in modulating a broad range of behaviors. Increasingly important cross‐species research of SN may require connectionally homogeneous and homologous subregions of SN as objective and stable starting points from which the evolutionary characteristics of brain could be inspected. However, existing atlases of SN were all inaccurate mappings as a cross‐species connectome atlas due to inadequate homology constraint during their constructions, and arbitrary paired use of these atlases might cause unreliable findings. In this study, a reliable blind‐source cross‐species parcellation of SN was developed based on the following rationale: striatonigrostriatal circuits form major structure of nigral connectivity; different nigral components have unique striatonigrostriatal connectivity; and inter‐species corresponding human and macaque nigral components have similar striatonigrostriatal connectivity. Specifically, all voxels in human and macaque SN were grouped together and then classified based on inter‐species identically characterized striatonigrostriatal connectivity attributes. Our results delineated a pars compacta‐pars reticulate‐like parcellation and further demonstrated its reliability by illustrating best‐matched whole‐brain structural and functional connectivity profiles of inter‐species corresponding nigral subregions. Detailed inter‐species and inter‐regional differences in multi‐aspect connectivities of these nigral subregions were inspected. It is expected that this cross‐species connectome atlas of SN can offer biologically reliable cornerstones and important information to facilitate future cross‐species research. [ABSTRACT FROM AUTHOR]

Published

2023

31. Symptomatic responses elicited by electrical stimulation of the cingulate cortex: Study of a cohort of epileptic patients and literature review.

Author

Xue, Yansong, Yan, Hao, Hao, Guiliang, Gao, Ying, Wang, Xueyuan, Ni, Duanyu, Qiao, Liang, Shu, Wei, and Yu, Tao

Subjects

*CINGULATE cortex, *LITERATURE reviews, *ELECTRIC stimulation, *PEOPLE with epilepsy, *EPILEPSY, *BRAIN mapping, *PREMOTOR cortex, *VAGUS nerve

Abstract

Our understanding of cingulate cortex function is limited. As a method for locating the epileptogenic zone, direct electrical cortical stimulation (ECS) provides an opportunity to understand the functional localization of the cingulate cortex. This study aimed to learn more about the function of the cingulate cortex by analyzing a large body of data from our center and by reviewing existing literature on cortical mapping. We retrospectively analyzed the ECS data of 124 patients with drug‐resistant epilepsy who had undergone electrode implantation in the cingulate cortex. The standard stimulation parameters included a biphasic pulse and bipolar stimulation at 50 Hz. Furthermore, we reviewed existing studies on cingulate responses elicited by the ECS and compared them with our results. A total of 329 responses were evoked in 276 contacts using ECS. Of these, 196 were physiological functional responses, which included sensory, affective, autonomic, language, visual, vestibular, and motor responses, along with a few other sensations. Sensory, motor, vestibular, and visual responses were concentrated in the cingulate sulcus visual area (CSv). Furthermore, 133 epilepsy‐related responses were evoked, most of which were concentrated in the ventral cingulate cortex. No responses were evoked by 498 contacts. Furthermore, the comparison of our ECS results with those reported in 11 comprehensive reviews revealed that the cingulate cortex is involved in complicated functions. The cingulate cortex is involved in sensory, affective, autonomic, language, visual, vestibular, and motor functions. The CSv is an integrating node of sensory, motor, vestibular, and visual systems. [ABSTRACT FROM AUTHOR]

Published

2023

32. The arrow‐of‐time in neuroimaging time series identifies causal triggers of brain function.

Author

Bolton, Thomas A. W., Van De Ville, Dimitri, Amico, Enrico, Preti, Maria G., and Liégeois, Raphaël

Subjects

*TIME series analysis, *BRAIN mapping, *BRAIN imaging, *NEURAL pathways, *PHENOMENOLOGICAL theory (Physics)

Abstract

Moving from association to causal analysis of neuroimaging data is crucial to advance our understanding of brain function. The arrow‐of‐time (AoT), that is, the known asymmetric nature of the passage of time, is the bedrock of causal structures shaping physical phenomena. However, almost all current time series metrics do not exploit this asymmetry, probably due to the difficulty to account for it in modeling frameworks. Here, we introduce an AoT‐sensitive metric that captures the intensity of causal effects in multivariate time series, and apply it to high‐resolution functional neuroimaging data. We find that causal effects underlying brain function are more distinctively localized in space and time than functional activity or connectivity, thereby allowing us to trace neural pathways recruited in different conditions. Overall, we provide a mapping of the causal brain that challenges the association paradigm of brain function. [ABSTRACT FROM AUTHOR]

Published

2023

33. Brain-wide network analysis of resting-state neuromagnetic data.

Author

Tetsuo Kida, Emi Tanaka, Ryusuke Kakigi, and Koji Inui

Subjects

*LARGE-scale brain networks, *STATISTICAL correlation, *BRAIN mapping, *DATA analysis, *GRAPH theory

Abstract

The present study performed a brain-wide network analysis of resting-state magnetoencephalograms recorded from 53 healthy participants to visualize elaborate brain maps of phase- and amplitude-derived graph-theory metrics at different frequencies. To achieve this, we conducted a vertex-wise computation of threshold-independent graph metrics by combining proportional thresholding and a conjunction analysis and applied them to a correlation analysis of age and brain networks. Source power showed a frequency-dependent cortical distribution. Threshold-independent graph metrics derived from phase- and amplitude-based connectivity showed similar or different distributions depending on frequency. Vertex-wise age-brain correlation maps revealed that source power at the beta band and the amplitude-based degree at the alpha band changed with age in local regions. The present results indicate that a brain-wide analysis of neuromagnetic data has the potential to reveal neurophysiological network features in the human brain in a resting state. [ABSTRACT FROM AUTHOR]

Published

2023

34. Mapping and decoding cortical engagement during motor imagery, mental arithmetic, and silent word generation using MEG.

Author

Youssofzadeh, Vahab, Roy, Sujit, Chowdhury, Anirban, Izadysadr, Aqil, Parkkonen, Lauri, Raghavan, Manoj, and Prasad, Girijesh

Subjects

*MOTOR imagery (Cognition), *MENTAL arithmetic, *BRAIN mapping, *STROKE, *BRAIN-computer interfaces

Abstract

Accurate quantification of cortical engagement during mental imagery tasks remains a challenging brain‐imaging problem with immediate relevance to developing brain–computer interfaces. We analyzed magnetoencephalography (MEG) data from 18 individuals completing cued motor imagery, mental arithmetic, and silent word generation tasks. Participants imagined movements of both hands (HANDS) and both feet (FEET), subtracted two numbers (SUB), and silently generated words (WORD). The task‐related cortical engagement was inferred from beta band (17–25 Hz) power decrements estimated using a frequency‐resolved beamforming method. In the hands and feet motor imagery tasks, beta power consistently decreased in premotor and motor areas. In the word and subtraction tasks, beta‐power decrements showed engagements in language and arithmetic processing within the temporal, parietal, and inferior frontal regions. A support vector machine classification of beta power decrements yielded high accuracy rates of 74 and 68% for classifying motor‐imagery (HANDS vs. FEET) and cognitive (WORD vs. SUB) tasks, respectively. From the motor‐versus‐nonmotor contrasts, excellent accuracy rates of 85 and 80% were observed for hands‐versus‐word and hands‐versus‐sub, respectively. A multivariate Gaussian‐process classifier provided an accuracy rate of 60% for the four‐way (HANDS‐FEET‐WORD‐SUB) classification problem. Individual task performance was revealed by within‐subject correlations of beta‐decrements. Beta‐power decrements are helpful metrics for mapping and decoding cortical engagement during mental processes in the absence of sensory stimuli or overt behavioral outputs. Markers derived based on beta decrements may be suitable for rehabilitation purposes, to characterize motor or cognitive impairments, or to treat patients recovering from a cerebral stroke. [ABSTRACT FROM AUTHOR]

Published

2023

35. Electroconvulsive therapy treatment responsive multimodal brain networks

Author

Qi, Shile, Abbott, Christopher C, Narr, Katherine L, Jiang, Rongtao, Upston, Joel, McClintock, Shawn M, Espinoza, Randall, Jones, Tom, Zhi, Dongmei, Sun, Hailun, Yang, Xiao, Sui, Jing, and Calhoun, Vince D

Subjects

Neurosciences, Mental Health, Clinical Research, Brain Disorders, Depression, Mental health, Neurological, Adolescent, Adult, Aged, Aged, 80 and over, Algorithms, Brain Mapping, Depressive Disorder, Major, Depressive Disorder, Treatment-Resistant, Electroconvulsive Therapy, Female, Humans, Magnetic Resonance Imaging, Male, Memory Disorders, Middle Aged, Multimodal Imaging, Nerve Net, Psychiatric Status Rating Scales, Treatment Outcome, Young Adult, depressive episodes, electroconvulsive therapy, multimodal fusion, treatment response, Cognitive Sciences, Experimental Psychology

Abstract

Electroconvulsive therapy is regarded as the most effective antidepressant treatment for severe and treatment-resistant depressive episodes. Despite the efficacy of electroconvulsive therapy, the neurobiological underpinnings and mechanisms underlying electroconvulsive therapy induced antidepressant effects remain unclear. The objective of this investigation was to identify electroconvulsive therapy treatment responsive multimodal biomarkers with the 17-item Hamilton Depression Rating Scale guided brain structure-function fusion in 118 patients with depressive episodes and 60 healthy controls. Results show that reduced fractional amplitude of low frequency fluctuations in the prefrontal cortex, insula and hippocampus, linked with increased gray matter volume in anterior cingulate, medial temporal cortex, insula, thalamus, caudate and hippocampus represent electroconvulsive therapy responsive covarying functional and structural brain networks. In addition, relative to nonresponders, responder-specific electroconvulsive therapy related brain networks occur in frontal-limbic network and are associated with successful therapeutic outcomes. Finally, electroconvulsive therapy responsive brain networks were unrelated to verbal declarative memory. Using a data-driven, supervised-learning method, we demonstrated that electroconvulsive therapy produces a remodeling of brain functional and structural covariance that was unique to antidepressant symptom response, but not linked to memory impairment.

Published

2020

36. Abnormal distraction and load‐specific connectivity during working memory in cognitively normal Parkinson's disease

Author

Harrington, Deborah L, Shen, Qian, Filoteo, Julian Vincent, Litvan, Irene, Huang, Mingxiong, Castillo, Gabriel N, Lee, Roland R, and Bayram, Ece

Subjects

Neurosciences, Clinical Research, Parkinson's Disease, Brain Disorders, Neurodegenerative, Aging, Mental Health, 2.1 Biological and endogenous factors, Aetiology, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Aged, Biological Specimen Banks, Brain Mapping, Cerebral Cortex, Executive Function, Female, Humans, Magnetic Resonance Imaging, Male, Memory Disorders, Memory, Short-Term, Mental Recall, Middle Aged, Neural Pathways, Neuropsychological Tests, Parkinson Disease, Prefrontal Cortex, Psychomotor Performance, Space Perception, Visual Perception, context-dependent functional connectivity, distraction, fMRI, memory load, Parkinson's disease, visuospatial, working memory, Cognitive Sciences, Experimental Psychology

Abstract

Visuospatial working memory impairments are common in Parkinson's disease (PD), yet the underlying neural mechanisms are poorly understood. The present study investigated abnormalities in context-dependent functional connectivity of working memory hubs in PD. Cognitively normal PD and control participants underwent fMRI while performing a visuospatial working memory task. To identify sources of dysfunction, distraction, and load-modulated connectivity were disentangled for encoding and retrieval phases of the task. Despite normal working memory performance in PD, two features of abnormal connectivity were observed, one due to a loss in normal context-related connectivity and another related to upregulated connectivity of hubs for which the controls did not exhibit context-dependent connectivity. During encoding, striatal-prefrontal coupling was lost in PD, both during distraction and high memory loads. However, long-range connectivity of prefrontal, medial temporal and occipital hubs was upregulated in a context-specific manner. Memory retrieval was characterized by different aberrant connectivity patterns, wherein precuneus connectivity was upregulated during distraction, whereas prefrontal couplings were lost as memory load approached capacity limits. Features of abnormal functional connectivity in PD had pathological and compensatory influences as they correlated with poorer working memory or better visuospatial skills. The results offer new insights into working memory-related signatures of aberrant cortico-cortical and corticostriatal functional connections, which may portend future declines in different facets of working memory.

Published

2020

37. Linking resting-state networks and social cognition in schizophrenia and bipolar disorder.

Author

Jimenez, Amy, Riedel, Philipp, Lee, Junghee, Reavis, Eric, and Green, Michael

Subjects

bipolar disorder, resting-state fMRI, schizophrenia, social cognition, Adolescent, Adult, Aged, Bipolar Disorder, Brain Mapping, Cognition, Cognition Disorders, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Nerve Net, Rest, Schizophrenia, Schizophrenic Psychology, Social Behavior, Young Adult

Abstract

Individuals with schizophrenia and bipolar disorder show alterations in functional neural connectivity during rest. However, resting-state network (RSN) disruptions have not been systematically compared between the two disorders. Further, the impact of RSN disruptions on social cognition, a key determinant of functional outcome, has not been studied. Forty-eight individuals with schizophrenia, 46 with bipolar disorder, and 48 healthy controls completed resting-state functional magnetic resonance imaging. An atlas-based approach was used to examine functional connectivity within nine RSNs across the cortex. RSN connectivity was assessed via nonparametric permutation testing, and associations with performance on emotion perception, mentalizing, and emotion management tasks were examined. Group differences were observed in the medial and lateral visual networks and the sensorimotor network. Individuals with schizophrenia demonstrated reduced connectivity relative to healthy controls in all three networks. Individuals with bipolar disorder demonstrated reduced connectivity relative to controls in the medial visual network and connectivity within this network was significantly positively correlated with emotion management. In healthy controls, connectivity within the medial and lateral visual networks positively correlated with mentalizing. No significant correlations were found for either visual network in schizophrenia. Results highlight the role of altered early visual processing in social cognitive deficits in both schizophrenia and bipolar disorder. However, individuals with bipolar disorder appear to compensate for disrupted visual network connectivity on social cognitive tasks, whereas those with schizophrenia do not. The current study adds clarity on the neurophysiology underlying social cognitive deficits that result in impaired functioning in serious mental illness.

Published

2019

38. Experimental design modulates variance in BOLD activation: The variance design general linear model

Author

Gaut, Garren, Li, Xiangrui, Lu, Zhong‐Lin, and Steyvers, Mark

Subjects

Biological Psychology, Psychology, Behavioral and Social Science, Neurosciences, Mental health, Neurological, Adult, Brain, Brain Mapping, Connectome, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Memory, Short-Term, Models, Theoretical, Research Design, brain mapping, functional magnetic resonance imaging, image processing, linear models, q-bio.NC, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Typical fMRI studies have focused on either the mean trend in the blood-oxygen-level-dependent (BOLD) time course or functional connectivity (FC). However, other statistics of the neuroimaging data may contain important information. Despite studies showing links between the variance in the BOLD time series (BV) and age and cognitive performance, a formal framework for testing these effects has not yet been developed. We introduce the variance design general linear model (VDGLM), a novel framework that facilitates the detection of variance effects. We designed the framework for general use in any fMRI study by modeling both mean and variance in BOLD activation as a function of experimental design. The flexibility of this approach allows the VDGLM to (a) simultaneously make inferences about a mean or variance effect while controlling for the other and (b) test for variance effects that could be associated with multiple conditions and/or noise regressors. We demonstrate the use of the VDGLM in a working memory application and show that engagement in a working memory task is associated with whole-brain decreases in BOLD variance.

Published

2019

39. Spatial dynamics within and between brain functional domains: A hierarchical approach to study time‐varying brain function

Author

Iraji, Armin, Fu, Zening, Damaraju, Eswar, DeRamus, Thomas P, Lewis, Noah, Bustillo, Juan R, Lenroot, Rhoshel K, Belger, Aysneil, Ford, Judith M, McEwen, Sarah, Mathalon, Daniel H, Mueller, Bryon A, Pearlson, Godfrey D, Potkin, Steven G, Preda, Adrian, Turner, Jessica A, Vaidya, Jatin G, Erp, Theo GM, and Calhoun, Vince D

Subjects

Neurosciences, Bioengineering, Neurological, Adolescent, Adult, Brain, Brain Mapping, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Models, Neurological, Young Adult, brain dynamic, functional domain, functional module, high-order independent component analysis, intrinsic activity, resting state fMRI, schizophrenia, spatial domain state, spatial dynamics, Cognitive Sciences, Experimental Psychology

Abstract

The analysis of time-varying activity and connectivity patterns (i.e., the chronnectome) using resting-state magnetic resonance imaging has become an important part of ongoing neuroscience discussions. The majority of previous work has focused on variations of temporal coupling among fixed spatial nodes or transition of the dominant activity/connectivity pattern over time. Here, we introduce an approach to capture spatial dynamics within functional domains (FDs), as well as temporal dynamics within and between FDs. The approach models the brain as a hierarchical functional architecture with different levels of granularity, where lower levels have higher functional homogeneity and less dynamic behavior and higher levels have less homogeneity and more dynamic behavior. First, a high-order spatial independent component analysis is used to approximate functional units. A functional unit is a pattern of regions with very similar functional activity over time. Next, functional units are used to construct FDs. Finally, functional modules (FMs) are calculated from FDs, providing an overall view of brain dynamics. Results highlight the spatial fluidity within FDs, including a broad spectrum of changes in regional associations, from strong coupling to complete decoupling. Moreover, FMs capture the dynamic interplay between FDs. Patients with schizophrenia show transient reductions in functional activity and state connectivity across several FDs, particularly the subcortical domain. Activity and connectivity differences convey unique information in many cases (e.g., the default mode) highlighting their complementarity information. The proposed hierarchical model to capture FD spatiotemporal variations provides new insight into the macroscale chronnectome and identifies changes hidden from existing approaches.

Published

2019

40. Distribution of brain iron accrual in adolescence: Evidence from cross‐sectional and longitudinal analysis

Author

Peterson, Eric T, Kwon, Dongjin, Luna, Beatriz, Larsen, Bart, Prouty, Devin, De Bellis, Michael D, Voyvodic, James, Liu, Chunlei, Li, Wei, Pohl, Kilian M, Sullivan, Edith V, and Pfefferbaum, Adolf

Subjects

Neurosciences, Substance Misuse, Biomedical Imaging, Clinical Research, Pediatric, Alcoholism, Alcohol Use and Health, Aetiology, 2.1 Biological and endogenous factors, Neurological, Mental health, Good Health and Well Being, Adolescent, Aging, Brain, Brain Chemistry, Brain Mapping, Child, Cross-Sectional Studies, Diffusion Tensor Imaging, Female, Functional Laterality, Humans, Iron, Longitudinal Studies, Magnetic Resonance Imaging, Male, Neuropsychological Tests, Putamen, Red Nucleus, Young Adult, adolescent, DTI, fMRI, iron, MRI, QSM, susceptibility, SWI, Cognitive Sciences, Experimental Psychology

Abstract

To track iron accumulation and location in the brain across adolescence, we repurposed diffusion tensor imaging (DTI) and functional magnetic resonance imaging (fMRI) data acquired in 513 adolescents and validated iron estimates with quantitative susceptibility mapping (QSM) in 104 of these subjects. DTI and fMRI data were acquired longitudinally over 1 year in 245 male and 268 female, no-to-low alcohol-consuming adolescents (12-21 years at baseline) from the National Consortium on Alcohol and NeuroDevelopment in Adolescence (NCANDA) study. Brain region average signal values were calculated for susceptibility to nonheme iron deposition: pallidum, putamen, dentate nucleus, red nucleus, and substantia nigra. To estimate nonheme iron, the corpus callosum signal (robust to iron effects) was divided by regional signals to generate estimated R2 (edwR2 for DTI) and R2 * (eR2 * for fMRI). Longitudinal iron deposition was measured using the normalized signal change across time for each subject. Validation using baseline QSM, derived from susceptibility-weighted imaging, was performed on 46 male and 58 female participants. Normalized iron deposition estimates from DTI and fMRI correlated with age in most regions; both estimates indicated less iron in boys than girls. QSM results correlated highly with DTI and fMRI results (adjusted R2 = 0.643 for DTI, 0.578 for fMRI). Cross-sectional and longitudinal analyses indicated an initial rapid increase in iron, notably in the putamen and red nucleus, that slowed with age. DTI and fMRI data can be repurposed for identifying regional brain iron deposition in developing adolescents as validated with high correspondence with QSM.

Published

2019

41. fMRI evidence of aberrant neural adaptation for objects in schizophrenia and bipolar disorder

Author

Lee, Junghee, Reavis, Eric A, Engel, Stephen A, Altshuler, Lori L, Cohen, Mark S, Glahn, David C, Nuechterlein, Keith H, Wynn, Jonathan K, and Green, Michael F

Subjects

Serious Mental Illness, Brain Disorders, Clinical Research, Neurosciences, Mental Health, Eye Disease and Disorders of Vision, Schizophrenia, Neurological, Mental health, Adaptation, Psychological, Adolescent, Adult, Aged, Bipolar Disorder, Brain Mapping, Discrimination, Psychological, Female, Gyrus Cinguli, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Occipital Lobe, Psychiatric Status Rating Scales, Schizophrenic Psychology, Visual Cortex, Visual Perception, Young Adult, bipolar disorder, fMRI adaptation, neural tuning, object processing, schizophrenia, Cognitive Sciences, Experimental Psychology

Abstract

Functional magnetic resonance imaging (fMRI) adaptation (also known as fMRI repetition suppression) has been widely used to characterize stimulus selectivity in vivo, a fundamental feature of neuronal processing in the brain. We investigated whether SZ patients and BD patients show aberrant fMRI adaptation for object perception. About 52 SZ patients, 55 BD patients, and 53 community controls completed an object discrimination task with three conditions: the same object presented twice, two exemplars from the same category, and two exemplars from different categories. We also administered two functional localizer tasks. A region of interest analysis was employed to evaluate a priori hypotheses about the lateral occipital complex (LOC) and early visual cortex (EVC). An exploratory whole brain analysis was also conducted. In the LOC and EVC, controls showed the expected reduced fMRI responses to repeated presentation of the same objects compared with different objects (i.e., fMRI adaptation for objects, p

Published

2019

42. MEG imaging of recurrent gliomas reveals functional plasticity of hemispheric language specialization

Author

Traut, Tavish, Sardesh, Nina, Bulubas, Lucia, Findlay, Anne, Honma, Susanne M, Mizuiri, Danielle, Berger, Mitchel S, Hinkley, Leighton B, Nagarajan, Srikantan S, and Tarapore, Phiroz E

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Brain Disorders, Cancer, Clinical Research, Brain Cancer, Biomedical Imaging, Rare Diseases, Prevention, Adolescent, Adult, Aged, Brain Mapping, Brain Neoplasms, Female, Functional Laterality, Glioma, Humans, Language, Magnetoencephalography, Male, Middle Aged, Neoplasm Recurrence, Local, Neuroimaging, Neuronal Plasticity, Retrospective Studies, Young Adult, brain tumor, glioma, language dominance, language laterality index, language lateralization, magnetoencephalography, neurosurgery, recurrence, verb generation, Neurosciences, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

In patients with gliomas, changes in hemispheric specialization for language determined by magnetoencephalography (MEG) were analyzed to elucidate the impact of treatment and tumor recurrence on language networks. Demonstration of reorganization of language networks in these patients has significant implications on the prevention of postoperative functional loss and recovery. Whole-brain activity during an auditory verb generation task was estimated from MEG recordings in a group of 73 patients with recurrent gliomas. Hemisphere of language dominance was estimated using the language laterality index (LI), a measure derived from the task. The initial scan was performed prior to resection; patients subsequently underwent surgery and adjuvant treatment. A second scan was performed upon recurrence prior to repeat resection. The relationship between the shift in LI between scans and demographics, anatomic location, pathology, and adjuvant treatment was analyzed. Laterality shifts were observed between scans; the median percent change was 29.1% across all patients. Laterality shift magnitude and relative direction were associated with the initial position of language dominance; patients with increased lateralization experienced greater shifts than those presenting more bilateral representation. A change in LI from left or right to bilateral (or vice versa) occurred in 23.3% of patients; complete switch occurred in 5.5% of patients. Patients with tumors within the language-dominant hemisphere experienced significantly greater shifts than those with contralateral tumors. The majority of patients with glioma experience shifts in language network organization over time which correlate with the relative position of language lateralization and tumor location.

Published

2019

43. Sex differences in own and other body perception

Author

Burke, Sarah M, Majid, DS Adnan, Manzouri, Amir H, Moody, Teena, Feusner, Jamie D, and Savic, Ivanka

Subjects

Brain Disorders, Behavioral and Social Science, Basic Behavioral and Social Science, Neurosciences, Mental Health, Clinical Research, Eating Disorders, 2.3 Psychological, social and economic factors, Aetiology, 1.2 Psychological and socioeconomic processes, Underpinning research, Mental health, Adult, Attention, Brain Mapping, Cerebral Cortex, Female, Humans, Magnetic Resonance Imaging, Male, Neostriatum, Reward, Self Concept, Sex Characteristics, Sex Factors, Social Perception, Visual Perception, Young Adult, body perception, fMRI, other body, own body, sex differences, Cognitive Sciences, Experimental Psychology

Abstract

Own body perception, and differentiating and comparing one's body to another person's body, are common cognitive functions that have relevance for self-identity and social interactions. In several psychiatric conditions, including anorexia nervosa, body dysmorphic disorder, gender dysphoria, and autism spectrum disorder, self and own body perception, as well as aspects of social communication are disturbed. Despite most of these conditions having skewed prevalence sex ratios, little is known about whether the neural basis of own body perception differs between the sexes. We addressed this question by investigating brain activation using functional magnetic resonance imaging during a Body Perception task in 15 male and 15 female healthy participants. Participants viewed their own body, bodies of same-sex, or opposite-sex other people, and rated the degree that they appeared like themselves. We found that men and women did not differ in the pattern of brain activation during own body perception compared to a scrambled control image. However, when viewing images of other bodies of same-sex or opposite-sex, men showed significantly stronger activations in attention-related and reward-related brain regions, whereas women engaged stronger activations in striatal, medial-prefrontal, and insular cortices, when viewing the own body compared to other images of the opposite sex. It is possible that other body images, particularly of the opposite sex, may be of greater salience for men, whereas images of own bodies may be more salient for women. These observations provide tentative neurobiological correlates to why women may be more vulnerable than men to conditions involving own body perception.

Published

2019

44. Differential brain mechanisms for processing distracting information in task‐relevant and ‐irrelevant dimensions in visual search

Author

Wei, Ping, Yu, Hongbo, Müller, Hermann J, Pollmann, Stefan, and Zhou, Xiaolin

Subjects

Biological Psychology, Psychology, Basic Behavioral and Social Science, Neurosciences, Eye Disease and Disorders of Vision, Behavioral and Social Science, Clinical Research, Neurological, Adult, Attention, Brain Mapping, Cerebral Cortex, Female, Humans, Magnetic Resonance Imaging, Male, Psychomotor Performance, Space Perception, Visual Perception, Young Adult, conjunction search, feature search, fMRI, task-irrelevant, task-relevant, visual search, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

A crucial function of our goal-directed behavior is to select task-relevant targets among distractor stimuli, some of which may share properties with the target and thus compete for attentional selection. Here, by applying functional magnetic resonance imaging (fMRI) to a visual search task in which a target was embedded in an array of distractors that were homogeneous or heterogeneous along the task-relevant (orientation or form) and/or task-irrelevant (color) dimensions, we demonstrate that for both (orientation) feature search and (form) conjunction search, the fusiform gyrus is involved in processing the task-irrelevant color information, while the bilateral frontal eye fields (FEF), the cortex along the left intraparietal sulcus (IPS), and the left junction of intraparietal and transverse occipital sulci (IPTO) are involved in processing task-relevant distracting information, especially for target-absent trials. Moreover, in conjunction (but not in feature) search, activity in these frontoparietal regions is affected by stimulus heterogeneity along the task-irrelevant dimension: heterogeneity of the task-irrelevant information increases the activity in these regions only when the task-relevant information is homogeneous, not when it is heterogeneous. These findings suggest that differential neural mechanisms are involved in processing task-relevant and task-irrelevant dimensions of the searched-for objects. In addition, they show that the top-down task set plays a dominant role in determining whether or not task-irrelevant information can affect the processing of the task-relevant dimension in the frontoparietal regions.

Published

2019

45. Deep in the brain: Changes in subcortical function immediately preceding a migraine attack

Author

Meylakh, Noemi, Marciszewski, Kasia K, Di Pietro, Flavia, Macefield, Vaughan G, Macey, Paul M, and Henderson, Luke A

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Pain Research, Migraines, Neurosciences, Brain Disorders, Chronic Pain, Headaches, 2.1 Biological and endogenous factors, Aetiology, Neurological, Adult, Brain, Brain Mapping, Female, Gray Matter, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Middle Aged, Migraine Disorders, Neural Pathways, hypothalamus, infra-slow oscillations, periaqueductal gray matter, spinal trigeminal nucleus, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

The neural mechanism responsible for migraine remains unclear. While the role of an external trigger in migraine initiation remains vigorously debated, it is generally assumed that migraineurs display altered brain function between attacks. This idea stems from relatively few brain imaging studies with even fewer studies exploring changes in the 24 h period immediately prior to a migraine attack. Using functional magnetic resonance imaging, we measured infra-slow oscillatory activity, regional homogeneity, and connectivity strengths of resting activity in migraineurs directly before (n = 8), after (n = 11), and between migraine attacks (n = 26) and in healthy control subjects (n = 78). Comparisons between controls and each migraine group and between migraine groups were made for each of these measures. Directly prior to a migraine, increased infra-slow oscillatory activity occurred in brainstem and hypothalamic regions that also display altered activity during a migraine itself, that is, the spinal trigeminal nucleus, dorsal pons, and hypothalamus. Furthermore, these midbrain and hypothalamic sites displayed increased connectivity strengths and regional homogeneity directly prior to a migraine. Remarkably, these resting oscillatory and connectivity changes did not occur directly after or between migraine attacks and were significantly different to control subjects. These data provide evidence of altered brainstem and hypothalamic function in the period immediately before a migraine and raise the prospect that such changes contribute to the expression of a migraine attack.

Published

2018

46. The relationship between thalamic GABA content and resting cortical rhythm in neuropathic pain

Author

Di Pietro, Flavia, Macey, Paul M, Rae, Caroline D, Alshelh, Zeynab, Macefield, Vaughan G, Vickers, E Russell, and Henderson, Luke A

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Basic Behavioral and Social Science, Clinical Research, Peripheral Neuropathy, Neurodegenerative, Behavioral and Social Science, Pain Research, Chronic Pain, Aetiology, 2.1 Biological and endogenous factors, Neurological, Adult, Aged, Brain Mapping, Brain Waves, Cerebral Cortex, Electroencephalography, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Male, Middle Aged, Neuralgia, Rest, Thalamus, Young Adult, gamma-Aminobutyric Acid, chronic pain, electroencephalography, GABA, thalamocortical rhythm, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Recurrent thalamocortical connections are integral to the generation of brain rhythms and it is thought that the inhibitory action of the thalamic reticular nucleus is critical in setting these rhythms. Our work and others' has suggested that chronic pain that develops following nerve injury, that is, neuropathic pain, results from altered thalamocortical rhythm, although whether this dysrhythmia is associated with thalamic inhibitory function remains unknown. In this investigation, we used electroencephalography and magnetic resonance spectroscopy to investigate cortical power and thalamic GABAergic concentration in 20 patients with neuropathic pain and 20 pain-free controls. First, we found thalamocortical dysrhythmia in chronic orofacial neuropathic pain; patients displayed greater power than controls over the 4-25 Hz frequency range, most marked in the theta and low alpha bands. Furthermore, sensorimotor cortex displayed a strong positive correlation between cortical power and pain intensity. Interestingly, we found no difference in thalamic GABA concentration between pain subjects and control subjects. However, we demonstrated significant linear relationships between thalamic GABA concentration and enhanced cortical power in pain subjects but not controls. Whilst the difference in relationship between thalamic GABA concentration and resting brain rhythm between chronic pain and control subjects does not prove a cause and effect link, it is consistent with a role for thalamic inhibitory neurotransmitter release, possibly from the thalamic reticular nucleus, in altered brain rhythms in individuals with chronic neuropathic pain.

Published

2018

47. At the core of reasoning: Dissociating deductive and non‐deductive load

Author

Coetzee, John P and Monti, Martin M

Subjects

Clinical Research, Neurosciences, Mental health, Adolescent, Brain, Brain Mapping, Female, Humans, Language, Magnetic Resonance Imaging, Male, Pattern Recognition, Visual, Problem Solving, Young Adult, cognitive load, deduction, fMRI, language, propositional calculus, reasoning, Cognitive Sciences, Experimental Psychology

Abstract

In recent years, neuroimaging methods have been used to investigate how the human mind carries out deductive reasoning. According to some, the neural substrate of language is integral to deductive reasoning. According to others, deductive reasoning is supported by a language-independent distributed network including left frontopolar and frontomedial cortices. However, it has been suggested that activity in these frontal regions might instead reflect non-deductive factors such as working memory load and general cognitive difficulty. To address this issue, 20 healthy volunteers participated in an fMRI experiment in which they evaluated matched simple and complex deductive and non-deductive arguments in a 2 × 2 design. The contrast of complex versus simple deductive trials resulted in a pattern of activation closely matching previous work, including frontopolar and frontomedial "core" areas of deduction as well as other "cognitive support" areas in frontoparietal cortices. Conversely, the contrast of complex and simple non-deductive trials resulted in a pattern of activation that does not include any of the aforementioned "core" areas. Direct comparison of the load effect across deductive and non-deductive trials further supports the view that activity in the regions previously interpreted as "core" to deductive reasoning cannot merely reflect non-deductive load, but instead might reflect processes specific to the deductive calculus. Finally, consistent with previous reports, the classical language areas in left inferior frontal gyrus and posterior temporal cortex do not appear to participate in deductive inference beyond their role in encoding stimuli presented in linguistic format.

Published

2018

48. Intrinsic functional connectivity of the central extended amygdala

Author

Tillman, Rachael M, Stockbridge, Melissa D, Nacewicz, Brendon M, Torrisi, Salvatore, Fox, Andrew S, Smith, Jason F, and Shackman, Alexander J

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Psychology, Neurosciences, Mental Health, 1.1 Normal biological development and functioning, Underpinning research, Mental health, Neurological, Adolescent, Adult, Amygdala, Brain Mapping, Female, Humans, Magnetic Resonance Imaging, Male, Neural Pathways, Rest, Young Adult, affective neuroscience, amygdala, anxiety, bed nucleus of the stria terminalis, central extended amygdala, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

The central extended amygdala (EAc)-including the bed nucleus of the stria terminalis (BST) and central nucleus of the amygdala (Ce)-plays a critical role in triggering fear and anxiety and is implicated in the development of a range of debilitating neuropsychiatric disorders. Although it is widely believed that these disorders reflect the coordinated activity of distributed neural circuits, the functional architecture of the EAc network and the degree to which the BST and the Ce show distinct patterns of functional connectivity is unclear. Here, we used a novel combination of imaging approaches to trace the connectivity of the BST and the Ce in 130 healthy, racially diverse, community-dwelling adults. Multiband imaging, high-precision registration techniques, and spatially unsmoothed data maximized anatomical specificity. Using newly developed seed regions, whole-brain regression analyses revealed robust functional connectivity between the BST and Ce via the sublenticular extended amygdala, the ribbon of subcortical gray matter encompassing the ventral amygdalofugal pathway. Both regions displayed coupling with the ventromedial prefrontal cortex (vmPFC), midcingulate cortex (MCC), insula, and anterior hippocampus. The BST showed stronger connectivity with the thalamus, striatum, periaqueductal gray, and several prefrontal territories. The only regions showing stronger functional connectivity with the Ce were neighboring regions of the dorsal amygdala, amygdalohippocampal area, and anterior hippocampus. These observations provide a baseline against which to compare a range of special populations, inform our understanding of the role of the EAc in normal and pathological fear and anxiety, and showcase image registration techniques that are likely to be useful for researchers working with "deidentified" neuroimaging data.

Published

2018

49. Fronto‐parietal coding of goal‐directed actions performed by artificial agents

Author

Kupferberg, Aleksandra, Iacoboni, Marco, Flanagin, Virginia, Huber, Markus, Kasparbauer, Anna, Baumgartner, Thomas, Hasler, Gregor, Schmidt, Florian, Borst, Christoph, and Glasauer, Stefan

Subjects

Biological Psychology, Psychology, Clinical Research, Underpinning research, 1.2 Psychological and socioeconomic processes, Adult, Brain Mapping, Female, Frontal Lobe, Goals, Humans, Male, Motion Perception, Parietal Lobe, Social Perception, Theory of Mind, Young Adult, Neurosciences, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

With advances in technology, artificial agents such as humanoid robots will soon become a part of our daily lives. For safe and intuitive collaboration, it is important to understand the goals behind their motor actions. In humans, this process is mediated by changes in activity in fronto-parietal brain areas. The extent to which these areas are activated when observing artificial agents indicates the naturalness and easiness of interaction. Previous studies indicated that fronto-parietal activity does not depend on whether the agent is human or artificial. However, it is unknown whether this activity is modulated by observing grasping (self-related action) and pointing actions (other-related action) performed by an artificial agent depending on the action goal. Therefore, we designed an experiment in which subjects observed human and artificial agents perform pointing and grasping actions aimed at two different object categories suggesting different goals. We found a signal increase in the bilateral inferior parietal lobule and the premotor cortex when tool versus food items were pointed to or grasped by both agents, probably reflecting the association of hand actions with the functional use of tools. Our results show that goal attribution engages the fronto-parietal network not only for observing a human but also a robotic agent for both self-related and social actions. The debriefing after the experiment has shown that actions of human-like artificial agents can be perceived as being goal-directed. Therefore, humans will be able to interact with service robots intuitively in various domains such as education, healthcare, public service, and entertainment.

Published

2018

50. Neural mechanisms of interference control in working memory capacity

Author

Bomyea, Jessica, Taylor, Charles T, Spadoni, Andrea D, and Simmons, Alan N

Subjects

Biological Psychology, Cognitive and Computational Psychology, Psychology, Basic Behavioral and Social Science, Behavioral and Social Science, Clinical Research, Neurosciences, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, Underpinning research, Mental health, Neurological, Brain, Brain Mapping, Executive Function, Female, Humans, Magnetic Resonance Imaging, Male, Memory, Short-Term, Mental Recall, Young Adult, cognitive control, fMRI, interference, working memory, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

The extent to which one can use cognitive resources to keep information in working memory is known to rely on (1) active maintenance of target representations and (2) downregulation of interference from irrelevant representations. Neurobiologically, the global capacity of working memory is thought to depend on the prefrontal and parietal cortices; however, the neural mechanisms involved in controlling interference specifically in working memory capacity tasks remain understudied. In this study, 22 healthy participants completed a modified complex working memory capacity task (Reading Span) with trials of varying levels of interference control demands while undergoing functional MRI. Neural activity associated with interference control demands was examined separately during encoding and recall phases of the task. Results suggested a widespread network of regions in the prefrontal, parietal, and occipital cortices, and the cingulate and cerebellum associated with encoding, and parietal and occipital regions associated with recall. Results align with prior findings emphasizing the importance of frontoparietal circuits for working memory performance, including the role of the inferior frontal gyrus, cingulate, occipital cortex, and cerebellum in regulation of interference demands.

Published

2018