Your search keyword '"FA, Fractional Anisotropy"' showing total 3 results

1. White matter and task-switching in young adults: A Diffusion Tensor Imaging study

Author

Domenico D'Avella, Eleonora Mastrorilli, Alessandra Bertoldo, Antonino Vallesi, and Francesco Causin

Subjects

Male, Task switching, FSL, corpus callosum, executive functions, fractional anisotropy, radial diffusivity, task-switching, Neuropsychological Tests, Corpus callosum, Tonic (physiology), Developmental psychology, Executive Function, 0302 clinical medicine, FA, fractional anisotropy, General Neuroscience, 05 social sciences, Brain, Executive functions, EPI, echo-planar image, Magnetic Resonance Imaging, White Matter, RD, radial diffusivity, Diffusion Tensor Imaging, medicine.anatomical_structure, fMRI, functional magnetic resonance imaging, Visual Perception, Regression Analysis, Female, Psychology, psychological phenomena and processes, Cognitive psychology, Adult, MNI, Montreal Neurological Institute, Neuroscience(all), DTI, Diffusion Tensor Imaging, behavioral disciplines and activities, Article, 050105 experimental psychology, Lateralization of brain function, White matter, Young Adult, 03 medical and health sciences, Fractional anisotropy, Reaction Time, medicine, Humans, 0501 psychology and cognitive sciences, WM, white matter, Linguistics, ROIs, Regions Of Interest, Space Perception, RTs, response times, SD, standard deviation, 030217 neurology & neurosurgery, Diffusion MRI

Abstract

Highlights • DTI and performance data on three task-switching paradigms were collected on young adults. • Frontal inter-hemispheric white matter integrity favors sustained task-switching. • This result was observed when switching between spatial rules or color-shape ones. • No relation between behavior and white matter was observed for verbal rule switching. • Task-specific features determine whether white matter mediates task-switching performance., The capacity to flexibly switch between different task rules has been previously associated with distributed fronto-parietal networks, predominantly in the left hemisphere for phasic switching sub-processes, and in the right hemisphere for more tonic aspects of task-switching, such as rule maintenance and management. It is thus likely that the white matter (WM) connectivity between these regions is critical in sustaining the flexibility required by task-switching. This study examined the relationship between WM microstructure in young adults and task-switching performance in different paradigms: classical shape-color, spatial and grammatical tasks. The main results showed an association between WM integrity in anterior portions of the corpus callosum (genu and body) and a sustained measure of task-switching performance. In particular, a higher fractional anisotropy and a lower radial diffusivity in these WM regions were associated with smaller mixing costs both in the spatial task-switching paradigm and in the shape-color one, as confirmed by a conjunction analysis. No association was found with behavioral measures obtained in the grammatical task-switching paradigm. The switch costs, a measure of phasic switching processes, were not correlated with WM microstructure in any task. This study shows that a more efficient inter-hemispheric connectivity within the frontal lobes favors sustained task-switching processes, especially with task contexts embedding non-verbal components.

Published

2016

2. Unraveling the secrets of white matter - Bridging the gap between cellular, animal and human imaging studies

Author

Walhovd, K.B., Johansen-Berg, H., and Káradóttir, R.T.

Subjects

OPCs, oligodendrocyte precursor cells, anatomy, Neuroscience(all), Neuroimaging, Review, CSF, cerebrospinal fluid, ASL, Arterial Spin Labeling, DWI, diffusion-weighted imaging, Animals, Humans, FA, fractional anisotropy, Myelin Sheath, functional imaging, MD, mean diffusivity, Brain Mapping, glial cell, ROIs, regions of interest, Immunohistochemistry, Magnetic Resonance Imaging, White Matter, myelin, Microscopy, Electron, DTI, fMRI, functional MRI, PLIC, posterior limb of the internal capsule, DTI, diffusion tensor imaging, MRI, magnetic resonance imaging, Neuroglia

Abstract

Highlights • White matter macrostructural measurements explained. • Introduction to how MRI imaging can be used to understand changes within the white matter. • Estimation of the white matter microstructures, cells and axons, occupying an imaging voxel. • Biological methods used for white matter studies explained., The CNS white matter makes up about half of the human brain, and with advances in human imaging it is increasingly becoming clear that changes in the white matter play a major role in shaping human behavior and learning. However, the mechanisms underlying these white matter changes remain poorly understood. Within this special issue of Neuroscience on white matter, recent advances in our knowledge of the function of white matter, from the molecular level to human imaging, are reviewed. Collaboration between fields is essential to understand the function of the white matter, but due to differences in methods and field-specific ‘language’, communication is often hindered. In this review, we try to address this hindrance by introducing the methods and providing a basic background to myelin biology and human imaging as a prelude to the other reviews within this special issue.

Published

2014

3. Magnetic resonance imaging of Huntington's disease: preparing for clinical trials

Author

Robert Christian Wolf, Susie M.D. Henley, Nicola Z. Hobbs, Jan Kassubek, Richard S. J. Frackowiak, Stefan Klöppel, and Sarah J. Tabrizi

Subjects

ROI, region of interest, Neurological Disorder, Review, CSF, cerebrospinal fluid, PD, Parkinson's disease, 0302 clinical medicine, Degenerative disease, DWI, diffusion-weighted imaging, TIV, total intracranial volume, FWHM, full-width at half-maximum, HD, Huntington's disease, FA, fractional anisotropy, Prefrontal cortex, PSC, presymptomatic gene carriers, 0303 health sciences, education.field_of_study, Clinical Trials as Topic, medicine.diagnostic_test, General Neuroscience, BSI, brain boundary shift integral, imaging, Huntington's disease, Magnetic Resonance Imaging, ICA, independent component analysis, TCN, temporally coherent networks, 3. Good health, Huntington Disease, fMRI, functional magnetic resonance imaging, basal ganglia, AD, Alzheimer's disease, Psychology, Neuroscience(all), Population, 03 medical and health sciences, VBM, voxel-based morphometry, Neuroimaging, medicine, Animals, Humans, WM, white matter, education, 030304 developmental biology, BOLD, blood-oxygenation level dependent, subject stratification, Magnetic resonance imaging, Voxel-based morphometry, GM, grey matter, medicine.disease, Functional imaging, Neuroscience, MRI, magnetic resonance imaging, 030217 neurology & neurosurgery, Biomarkers

Abstract

The known genetic mutation causing Huntington's disease (HD) makes this disease an important model to study links between gene and brain function. An autosomal dominant family history and the availability of a sensitive and specific genetic test allow pre-clinical diagnosis many years before the onset of any typical clinical signs. This review summarizes recent magnetic resonance imaging (MRI)–based findings in HD with a focus on the requirements if imaging is to be used in treatment trials. Despite its monogenetic cause, HD presents with a range of clinical manifestations, not explained by variation in the number of CAG repeats in the affected population. Neuroimaging studies have revealed a complex pattern of structural and functional changes affecting widespread cortical and subcortical regions far beyond the confines of the striatal degeneration that characterizes this disorder. Besides striatal dysfunction, functional imaging studies have reported a variable pattern of increased and decreased activation in cortical regions in both pre-clinical and clinically manifest HD-gene mutation carriers. Beyond regional brain activation changes, evidence from functional and diffusion-weighted MRI further suggests disrupted connectivity between corticocortical and corticostriatal areas. However, substantial inconsistencies with respect to structural and functional changes have been reported in a number of studies. Possible explanations include methodological factors and differences in study samples. There may also be biological explanations but these are poorly characterized and understood at present. Additional insights into this phenotypic variability derived from study of mouse models are presented to explore this phenomenon.

Published

2008