Your search keyword '"William S. Kremen"' showing total 7 results

1. Altered lateralization of the cingulum in deployment‐related traumatic brain injury: An <scp>ENIGMA</scp> military‐relevant brain injury study

Author

Emily L Dennis, Mary R Newsome, Hannah M Lindsey, Maheen M Adams, Tara A Austin, Seth G Disner, Blessen C Eapen, Carrie Esopenko, Carol E Franz, Elbert Geuze, Courtney Haswell, Sidney R Hinds, Cooper B Hodges, Andrei Irimia, Kimbra Kenney, Inga K Koerte, William S Kremen, Harvey S Levin, Rajendra A Morey, John Ollinger, Jared A Rowland, Randall S Scheibel, Martha E Shenton, Danielle R Sullivan, Leah D Talbert, Sophia I Thomopoulos, Maya Troyanskaya, William C Walker, Xin Wang, Ashley L Ware, J Kent Werner, Wright Williams, Paul M Thompson, David F Tate, and Elisabeth A Wilde

Subjects

Adult, Traumatic, Physical Injury - Accidents and Adverse Effects, 6.6 Psychological and behavioural, Neuropsychological Tests, Traumatic Brain Injury (TBI), Humans, Radiology, Nuclear Medicine and imaging, military, Traumatic Head and Spine Injury, Radiological and Ultrasound Technology, traumatic brain injury, Neurosciences, Brain, Evaluation of treatments and therapeutic interventions, Experimental Psychology, White Matter, Brain Disorders, Mental Health, Neurology, DTI, Brain Injuries, Neurological, Biomedical Imaging, Cognitive Sciences, Neurology (clinical), Anatomy

Abstract

Traumatic brain injury (TBI), a significant concern in military populations, is associated with alterations in brain structure and function, cognition, as well as physical and psychological dysfunction. Diffusion magnetic resonance imaging (dMRI) is particularly sensitive to changes in brain structure following TBI, as alterations in white matter (WM) microstructure are common. However, dMRI studies in mild TBI (mTBI) are conflicting, likely due to relatively small samples, sample heterogeneity (demographics, pre- and comorbidities) and injury characteristics (mechanism; chronicity). Furthermore, few studies account for brain asymmetry, which may impact cognitive functions subserved by WM tracts. Examining brain asymmetry in large samples may increase sensitivity to detect heterogeneous areas of subtle WM alteration in mTBI.Through the Enhancing Neuroimaging and Genetics through Meta-analysis (ENIGMA) Military-Relevant Brain Injury working group, we conducted a mega-analysis of neuroimaging and clinical data from 16 cohorts of Active Duty Service Members and Veterans (n=2,598; 2,321 males/277 females; age 19-85 years). 1,080 reported a deployment-related TBI, 480 had a history of only non-military-related TBI, 823 reported no history of TBI, and 215 did not differentiate between military and non-military TBI. dMRI data were processed in a harmonized manner along with harmonized demographic, injury, psychiatric, and cognitive measures. Hemispheric asymmetry of fractional anisotropy (FA, a common proxy for myelin organization) was calculated for 19 WM tracts and compared between those with and without TBI history.FA in the cingulum showed greater asymmetry in individuals with a history of deployment-related TBI; this effect was driven by greater left lateralization in the group with TBI. There was a trend towards lower FA of the right cingulum in the TBI group. These results remained significant after accounting for potentially confounding variables including posttraumatic stress disorder, depression, and handedness and were driven primarily by individuals who had sustained their worst TBI before age 40. We further found that alterations in the cingulum were associated with slower processing speed and poorer set shifting.The results indicate an enhancement of the previously reported natural left laterality, possibly due to vulnerability of the non-dominant hemisphere or compensatory mechanisms in the dominant hemisphere. The cingulum is one of the last WM tracts to mature, reaching peak FA around 42 years old. This effect was primarily detected in individuals whose worst injury occurred before age 40, suggesting that the protracted development of the cingulum may lead to increased vulnerability to insults, such as TBI.

Published

2022

2. Age-dependent white matter disruptions after military traumatic brain injury: Multivariate analysis results from ENIGMA brain injury

Author

Heather C. Bouchard, Delin Sun, Emily L. Dennis, Mary R. Newsome, Seth G. Disner, Jeremy Elman, Annelise Silva, Carmen Velez, Andrei Irimia, Nicholas D. Davenport, Scott R. Sponheim, Carol E. Franz, William S. Kremen, Michael J. Coleman, M. Wright Williams, Elbert Geuze, Inga K. Koerte, Martha E. Shenton, Maheen M. Adamson, Raul Coimbra, Gerald Grant, Lori Shutter, Mark S. George, Ross D. Zafonte, Thomas W. McAllister, Murray B. Stein, Paul M. Thompson, Elisabeth A. Wilde, David F. Tate, Aristeidis Sotiras, and Rajendra A. Morey

Subjects

Traumatic, Physical Injury - Accidents and Adverse Effects, Traumatic Brain Injury (TBI), diffusion MRI, Stress Disorders, Post-Traumatic, mTBI, Clinical Research, Brain Injuries, Traumatic, Humans, Radiology, Nuclear Medicine and imaging, military, Traumatic Head and Spine Injury, Brain Concussion, Stress Disorders, Veterans, Radiological and Ultrasound Technology, traumatic brain injury, ENIGMA, Neurosciences, nonnegative matrix factorization, Brain, Experimental Psychology, White Matter, Brain Disorders, Mental Health, Military Personnel, Neurology, Brain Injuries, Multivariate Analysis, Post-Traumatic, Biomedical Imaging, Cognitive Sciences, Neurology (clinical), Anatomy

Abstract

Mild Traumatic brain injury (mTBI) is a signature wound in military personnel, and repetitive mTBI has been linked to age-related neurogenerative disorders that affect white matter (WM) in the brain. However, findings of injury to specific WM tracts have been variable and inconsistent. This may be due to the heterogeneity of mechanisms, etiology, and comorbid disorders related to mTBI. Non-negative matrix factorization (NMF) is a data-driven approach that detects covarying patterns (components) within high-dimensional data. We applied NMF to diffusion imaging data from military Veterans with and without a self-reported TBI history. NMF identified 12 independent components derived from fractional anisotropy (FA) in a large dataset (n= 1,475) gathered through the ENIGMA (Enhancing Neuroimaging Genetics through Meta-Analysis) Military Brain Injury working group. Regressions were used to examine TBI- and mTBI-related associations in NMF-derived components while adjusting for age, sex, post-traumatic stress disorder, depression, and data acquisition site/scanner. We found significantly stronger age-dependent effects of lower FA in Veterans with TBI than Veterans without in four components (q&nbsp

Published

2021

3. Genetic architecture of hippocampal subfields on standard resolution MRI: How the parts relate to the whole

Author

Michael J. Lyons, Anders M. Dale, Michael C. Neale, William S. Kremen, Donald J. Hagler, Nathan A. Gillespie, Carol E. Franz, Jeremy A. Elman, Christine Fennema-Notestine, Linda K. McEvoy, Lisa T. Eyler, and Matthew S. Panizzon

Subjects

Male, Aging, genetic structures, Image Processing, Twins, heritability, Hippocampal formation, Hippocampus, Automation, Computer-Assisted, 0302 clinical medicine, Image Processing, Computer-Assisted, automated segmentation, Veterans, hippocampal subregions, Human Connectome Project, Radiological and Ultrasound Technology, 05 social sciences, Experimental Psychology, Statistical, Middle Aged, Magnetic Resonance Imaging, genetic correlation, Phenotype, Neurology, Twin Studies as Topic, Female, Cognitive Sciences, Anatomy, Factor Analysis, Computational biology, Biology, Genetic correlation, Article, 050105 experimental psychology, Vietnam Conflict, 03 medical and health sciences, Genetic variation, Connectome, Humans, 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, Aged, Genetic association, Neurosciences, Genetic Variation, Heritability, Twin study, Genetic architecture, nervous system, genetic variance, Neurology (clinical), Factor Analysis, Statistical, 030217 neurology & neurosurgery, Genome-Wide Association Study

Abstract

The human hippocampus can be subdivided into subfields with unique functional properties and differential vulnerability to disease or neuropsychiatric conditions. Identifying genes that confer susceptibility to such processes is an important goal in developing treatments. Recent advances in automatic subfield segmentation from magnetic resonance images make it possible to use these measures as phenotypes in large-scale genome-wide association studies. Such analyses are likely to rely largely on standard resolution (~1mm isotropic) T(1)-weighted images acquired on 3.0T scanners. Determining whether the genetic architecture of subfields can be detected from such images is therefore an important step. We used Freesurfer v6.0 to segment hippocampal subfields in two large twin studies, the Vietnam Era Twin Study of Aging and the Human Connectome Project. We estimated heritability of subfields and the genetic overlap with total hippocampal volume. Heritability was similar across samples, but little genetic variance remained after accounting for genetic influences on total hippocampal volume. Importantly, we examined genetic relationships between subfields to determine whether subfields can be grouped based on a smaller number of underlying, genetically independent factors. We identified three genetic factors in both samples, but the high degree of cross-loadings precluded formation of genetically distinct groupings of subfields. These results confirm the reliability of Freesurfer v6.0 generated subfields across samples for phenotypic analyses. However, the current results suggest that it will be difficult for large-scale genetic analyses to identify subfield-specific genes that are distinct from both total hippocampal volume and other subfields using segmentations generated from standard resolution T(1)-weighted images.

Published

2018

4. Genetic influences on individual differences in longitudinal changes in global and subcortical brain volumes: Results of the ENIGMA plasticity working group

Author

Nicholas G. Martin, Matthew S. Panizzon, Karen A. Mather, William S. Kremen, Ian B. Hickie, Anbupalam Thalamuthu, David C. Glahn, Wei Wen, Xue Hua, Narelle K. Hansell, Marinka M.G. Koenis, Lucija Abramovic, Dorret I. Boomsma, Carol E. Franz, Suzanne C. Swagerman, Greig I. de Zubicaray, Rachel M. Brouwer, René S. Kahn, John H. Gilmore, Hugo G. Schnack, Margaret J. Wright, Perminder S. Sachdev, Neda Jahanshad, Hilleke E. Hulshoff Pol, Derrek P. Hibar, Katie L. McMahon, Nitin Gogtay, Paul M. Thompson, and Lachlan T. Strike

Subjects

Cerebellum, Radiological and Ultrasound Technology, 05 social sciences, Thalamus, Heritability, 050105 experimental psychology, 03 medical and health sciences, Lateral ventricles, 0302 clinical medicine, medicine.anatomical_structure, Neurology, Ageing, Neuroplasticity, Brain size, medicine, 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, sense organs, Neurology (clinical), Cognitive skill, Anatomy, skin and connective tissue diseases, Psychology, Neuroscience, 030217 neurology & neurosurgery

Abstract

Structural brain changes that occur during development and ageing are related to mental health and general cognitive functioning. Individuals differ in the extent to which their brain volumes change over time, but whether these differences can be attributed to differences in their genotypes has not been widely studied. Here we estimate heritability (h2) of changes in global and subcortical brain volumes in five longitudinal twin cohorts from across the world and in different stages of the lifespan (N = 861). Heritability estimates of brain changes were significant and ranged from 16% (caudate) to 42% (cerebellar gray matter) for all global and most subcortical volumes (with the exception of thalamus and pallidum). Heritability estimates of change rates were generally higher in adults than in children suggesting an increasing influence of genetic factors explaining individual differences in brain structural changes with age. In children, environmental influences in part explained individual differences in developmental changes in brain structure. Multivariate genetic modeling showed that genetic influences of change rates and baseline volume significantly overlapped for many structures. The genetic influences explaining individual differences in the change rate for cerebellum, cerebellar gray matter and lateral ventricles were independent of the genetic influences explaining differences in their baseline volumes. These results imply the existence of genetic variants that are specific for brain plasticity, rather than brain volume itself. Identifying these genes may increase our understanding of brain development and ageing and possibly have implications for diseases that are characterized by deviant developmental trajectories of brain structure.

Published

2017

5. Genetic and environmental influences on mean diffusivity and volume in subcortical brain regions

Author

Michael C. Neale, Carol E. Franz, Christine Fennema-Notestine, Linda K. McEvoy, Donald J. Hagler, Lisa T. Eyler, Matthew S. Panizzon, Nathan A. Gillespie, Anders M. Dale, William S. Kremen, and Michael J. Lyons

Subjects

0301 basic medicine, Radiological and Ultrasound Technology, Putamen, Brain morphometry, Thalamus, Caudate nucleus, Family aggregation, Neuropathology, Biology, Amygdala, Twin study, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Neurology, medicine, Radiology, Nuclear Medicine and imaging, Neurology (clinical), Anatomy, Neuroscience, 030217 neurology & neurosurgery

Abstract

Increased mean diffusivity (MD) is hypothesized to reflect tissue degeneration and may provide subtle indicators of neuropathology as well as age-related brain changes in the absence of volumetric differences. Our aim was to determine the degree to which genetic and environmental variation in subcortical MD is distinct from variation in subcortical volume. Data were derived from a sample of 387 male twins (83 MZ twin pairs, 55 DZ twin pairs, and 111 incomplete twin pairs) who were MRI scanned as part of the Vietnam Era Twin Study of Aging. Quantitative estimates of MD and volume for 7 subcortical regions were obtained: thalamus, caudate nucleus, putamen, pallidum, hippocampus, amygdala, and nucleus accumbens. After adjusting for covariates, bivariate twin models were fitted to estimate the size and significance of phenotypic, genotypic, and environmental correlations between MD and volume at each subcortical region. With the exception of the amygdala, familial aggregation in MD was entirely explained by additive genetic factors across all subcortical regions with estimates ranging from 46 to 84%. Based on bivariate twin modeling, variation in subcortical MD appears to be both genetically and environmentally unrelated to individual differences in subcortical volume. Therefore, subcortical MD may be an alternative biomarker of brain morphology for complex traits worthy of future investigation. Hum Brain Mapp 38:2589-2598, 2017. © 2017 Wiley Periodicals, Inc.

Published

2017

6. Heritability of white matter microstructure in late middle age: A twin study of tract-based fractional anisotropy and absolute diffusivity indices

Author

Eero, Vuoksimaa, Matthew S, Panizzon, Donald J, Hagler, Sean N, Hatton, Christine, Fennema-Notestine, Daniel, Rinker, Lisa T, Eyler, Carol E, Franz, Michael J, Lyons, Michael C, Neale, Ming T, Tsuang, Anders M, Dale, and William S, Kremen

Subjects

Male, Inheritance Patterns, Twins, Monozygotic, Middle Aged, White Matter, Article, Corpus Callosum, Diffusion Tensor Imaging, Residence Characteristics, Image Processing, Computer-Assisted, Twins, Dizygotic, Anisotropy, Humans, Gene-Environment Interaction, Aged, Retrospective Studies

Abstract

There is evidence that differences among individuals in white matter microstructure, as measured with diffusion tensor imaging (DTI), are under genetic control. However, little is known about the relative contribution of genetic and environmental effects on different diffusivity indices among late middle-aged adults. Here, we examined the magnitude of genetic influences for fractional anisotropy (FA), and mean (MD), axial (AD), and radial (RD) diffusivities in male twins aged 56-66 years old. Using an atlas-based registration approach to delineate individual white matter tracts, we investigated mean DTI-based indices within the corpus callosum, 12 bilateral tracts and all these regions of interest combined. All four diffusivity indices had high heritability at the global level (72%-80%). The magnitude of genetic effects in individual tracts varied from 0% to 82% for FA, 0% to 81% for MD, 8% to 77% for AD, and 0% to 80% for RD with most of the tracts showing significant heritability estimates. Despite the narrow age range of this community-based sample, age was correlated with all four diffusivity indices at the global level. In sum, all diffusion indices proved to have substantial heritability for most of the tracts and the heritability estimates were similar in magnitude for different diffusivity measures. Future studies could aim to discover the particular set of genes that underlie the significant heritability of white matter microstructure. Hum Brain Mapp 38:2026-2036, 2017. © 2017 Wiley Periodicals, Inc.

Published

2016

7. Genetic patterns of correlation among subcortical volumes in humans: Results from a magnetic resonance imaging twin study

Author

Ming T. Tsuang, Terry L. Jernigan, William S. Kremen, Lisa T. Eyler, Michael C. Neale, Nicholas C. Spitzer, Elizabeth Prom-Wormley, Bruce Fischl, Michele E. Perry, Larry J. Seidman, Anders M. Dale, Michael J. Lyons, Christine Fennema-Notestine, Jennifer Pacheco, Allison Stevens, Matthew S. Panizzon, J. Eric Schmitt, Heidi W. Thermenos, and Carol E. Franz

Subjects

Male, Individuality, Twins, Amygdala, Genetic correlation, Article, Basal ganglia, Genetic variation, medicine, Humans, Radiology, Nuclear Medicine and imaging, Behavioural genetics, Cerebral Cortex, Models, Genetic, Radiological and Ultrasound Technology, Putamen, Gene Expression Regulation, Developmental, Genetic Variation, Middle Aged, Twin study, medicine.anatomical_structure, Neurology, Cerebral cortex, Neurology (clinical), Anatomy, Psychology, Neuroscience

Abstract

Little is known about genetic influences on the volume of subcortical brain structures in adult humans, particularly whether there is regional specificity of genetic effects. Understanding patterns of genetic covariation among volumes of subcortical structures may provide insight into the development of individual differences that have consequences for cognitive and emotional behavior and neuropsychiatric disease liability. We measured the volume of 19 subcortical structures (including brain and ventricular regions) in 404 twins (110 monozygotic and 92 dizygotic pairs) from the Vietnam Era Twin Study of Aging and calculated the degree of genetic correlation among these volumes. We then examined the patterns of genetic correlation through hierarchical cluster analysis and by principal components analysis. We found that a model with four genetic factors best fit the data: a Basal Ganglia/Thalamus factor; a Ventricular factor; a Limbic factor; and a Nucleus Accumbens factor. Homologous regions from each hemisphere loaded on the same factors. The observed patterns of genetic correlation suggest the influence of multiple genetic influences. There is a genetic organization among structures which distinguishes between brain and cerebrospinal fluid spaces and between different subcortical regions. Further study is needed to understand this genetic patterning and whether it reflects influences on early development, functionally dependent patterns of growth or pruning, or regionally specific losses due to genes involved in aging, stress response, or disease.

Published

2010