Your search keyword '"diffusion MRI (dMRI)"' showing total 44 results

1. Impact of truncating diffusion MRI scans on diffusional kurtosis imaging.

Author

Fouto, Ana R., Henriques, Rafael N., Golub, Marc, Freitas, Andreia C., Ruiz-Tagle, Amparo, Esteves, Inês, Gil-Gouveia, Raquel, Silva, Nuno A., Vilela, Pedro, Figueiredo, Patrícia, and Nunes, Rita G.

Subjects

DIFFUSION tensor imaging, KURTOSIS, ACQUISITION of data, DIFFUSION magnetic resonance imaging, ANISOTROPY, HISTOGRAMS

Abstract

Objective: Diffusional kurtosis imaging (DKI) extends diffusion tensor imaging (DTI), characterizing non-Gaussian diffusion effects but requires longer acquisition times. To ensure the robustness of DKI parameters, data acquisition ordering should be optimized allowing for scan interruptions or shortening. Three methodologies were used to examine how reduced diffusion MRI scans impact DKI histogram-metrics: 1) the electrostatic repulsion model (OptEEM); 2) spherical codes (OptSC); 3) random (RandomTRUNC). Materials and methods: Pre-acquired diffusion multi-shell data from 14 female healthy volunteers (29±5 years) were used to generate reordered data. For each strategy, subsets containing different amounts of the full dataset were generated. The subsampling effects were assessed on histogram-based DKI metrics from tract-based spatial statistics (TBSS) skeletonized maps. To evaluate each subsampling method on simulated data at different SNRs and the influence of subsampling on in vivo data, we used a 3-way and 2-way repeated measures ANOVA, respectively. Results: Simulations showed that subsampling had different effects depending on DKI parameter, with fractional anisotropy the most stable (up to 5% error) and radial kurtosis the least stable (up to 26% error). RandomTRUNC performed the worst while the others showed comparable results. Furthermore, the impact of subsampling varied across distinct histogram characteristics, the peak value the least affected (OptEEM: up to 5% error; OptSC: up to 7% error) and peak height (OptEEM: up to 8% error; OptSC: up to 11% error) the most affected. Conclusion: The impact of truncation depends on specific histogram-based DKI metrics. The use of a strategy for optimizing the acquisition order is advisable to improve DKI robustness to exam interruptions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Exploring white matter dynamics and morphology through interactive numerical phantoms: the White Matter Generator.

Author

Winther, Sidsel, Peulicke, Oscar, Andersson, Mariam, Kjer, Hans M., Bærentzen, Jakob A., and Dyrby, Tim B.

Subjects

NEUROGLIA, WHITE matter (Nerve tissue), DIFFUSION magnetic resonance imaging, EXTRACELLULAR space, MONTE Carlo method

Abstract

Brain white matter is a dynamic environment that continuously adapts and reorganizes in response to stimuli and pathological changes. Glial cells, especially, play a key role in tissue repair, inflammation modulation, and neural recovery. The movements of glial cells and changes in their concentrations can influence the surrounding axon morphology. We introduce the White Matter Generator (WMG) tool to enable the study of how axon morphology is influenced through such dynamical processes, and how this, in turn, influences the diffusion-weighted MRI signal. This is made possible by allowing interactive changes to the configuration of the phantom generation throughout the optimization process. The phantoms can consist of myelinated axons, unmyelinated axons, and cell clusters, separated by extra-cellular space. Due to morphological flexibility and computational advantages during the optimization, the tool uses ellipsoids as building blocks for all structures; chains of ellipsoids for axons, and individual ellipsoids for cell clusters. After optimization, the ellipsoid representation can be converted to a mesh representation which can be employed in Monte-Carlo diffusion simulations. This offers an effective method for evaluating tissue microstructure models for diffusion-weighted MRI in controlled bio-mimicking white matter environments. Hence, the WMG offers valuable insights into white matter's adaptive nature and implications for diffusion-weighted MRI microstructure models, and thereby holds the potential to advance clinical diagnosis, treatment, and rehabilitation strategies for various neurological disorders and injuries. [ABSTRACT FROM AUTHOR]

Published

2024

3. White matter microstructure, traumatic brain injury, and disruptive behavior disorders in girls and boys.

Author

Guberman, Guido I., Theaud, Guillaume, Hawes, Samuel W., Ptito, Alain, Descoteaux, Maxime, and Hodgins, Sheilagh

Abstract

Introduction: Girls and boys presenting disruptive behavior disorders (DBDs) display differences in white matter microstructure (WMM) relative to typically developing (TD) sex-matched peers. Boys with DBDs are at increased risk for traumatic brain injuries (TBIs), which are also known to impact WMM. This study aimed to disentangle associations of WMM with DBDs and TBIs. Methods: The sample included 673 children with DBDs and 836 TD children, aged 9-10, from the Adolescent Brain Cognitive Development Study. Thirteen white matter bundles previously associated with DBDs were the focus of study. Analyses were undertaken separately by sex, adjusting for callous-unemotional traits (CU), attention-deficit hyperactivity disorder (ADHD), age, pubertal stage, IQ, ethnicity, and family income. Results: Among children without TBIs, those with DBDs showed sex-specific differences in WMM of several tracts relative to TD. Most differences were associated with ADHD, CU, or both. Greater proportions of girls and boys with DBDs than sex-matched TD children had sustained TBIs. Among girls and boys with DBDs, those who had sustained TBIs compared to those not injured, displayed WMM alterations that were robust to adjustment for all covariates. Across most DBD/TD comparisons, axonal density scores were higher among children presenting DBDs. Discussion: In conclusion, in this community sample of children, those with DBDs were more likely to have sustained TBIs that were associated with additional, sex-specific, alterations of WMM. These additional alterations further compromise the future development of children with DBDs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Investigating the potential of diffusion MRI in detecting early signs of neurodegenerative diseases.

Author

Kapoor, Shruti

Subjects

*DIFFUSION magnetic resonance imaging, *DIFFUSION tensor imaging, *ALZHEIMER'S disease, *PARKINSON'S disease, *EARLY diagnosis

Abstract

Neurodegenerative diseases, such as Alzheimer's and Parkinson's, are characterized by the progressive loss of structure and function of neurons. Early detection is crucial for effective intervention and management of these conditions. Diffusion Magnetic Resonance Imaging (dMRI) offers a non-invasive method to detect microstructural changes in the brain by measuring the diffusion of water molecules in tissues. This study investigates the potential of dMRI in identifying early signs of neurodegenerative diseases. A cohort of 100 participants, including healthy controls and individuals at high risk for neurodegenerative diseases, underwent dMRI scanning. Results indicate significant differences in diffusion metrics between the groups, suggesting that dMRI may be a valuable tool for early detection of neurodegenerative diseases. [ABSTRACT FROM AUTHOR]

Published

2024

5. Greater white matter degeneration and lower structural connectivity in non-amnestic vs. amnestic Alzheimer's disease.

Author

Phillips, Jeffrey S., Adluru, Nagesh, Chung, Moo K., Radhakrishnan, Hamsanandini, Olm, Christopher A., Cook, Philip A., Gee, James C., Cousins, Katheryn A. Q., Arezoumandan, Sanaz, Wolk, David A., McMillan, Corey T., Grossman, Murray, and Irwin, David J.

Subjects

ALZHEIMER'S disease, FRONTOTEMPORAL lobar degeneration, WHITE matter (Nerve tissue), AMNESTIC mild cognitive impairment, CEREBRAL atrophy, DIFFUSION magnetic resonance imaging

Abstract

Introduction: Multimodal evidence indicates Alzheimer's disease (AD) is characterized by early white matter (WM) changes that precede overt cognitive impairment. WM changes have overwhelmingly been investigated in typical, amnestic mild cognitive impairment and AD; fewer studies have addressed WM change in atypical, non-amnestic syndromes. We hypothesized each nonamnestic AD syndrome would exhibit WM differences from amnestic and other non-amnestic syndromes. Materials and methods: Participants included 45 cognitively normal (CN) individuals; 41 amnestic AD patients; and 67 patients with non-amnestic AD syndromes including logopenic-variant primary progressive aphasia (lvPPA, n = 32), posterior cortical atrophy (PCA, n = 17), behavioral variant AD (bvAD, n = 10), and corticobasal syndrome (CBS, n = 8). All had T1-weighted MRI and 30-direction diffusion-weighted imaging (DWI). We performed whole-brain deterministic tractography between 148 cortical and subcortical regions; connection strength was quantified by tractwise mean generalized fractional anisotropy. Regression models assessed effects of group and phenotype as well as associations with grey matter volume. Topological analyses assessed differences in persistent homology (numbers of graph components and cycles). Additionally, we tested associations of topological metrics with global cognition, disease duration, and DWI microstructural metrics. Results: Both amnestic and non-amnestic patients exhibited lower WM connection strength than CN participants in corpus callosum, cingulum, and inferior and superior longitudinal fasciculi. Overall, non-amnestic patients had more WM disease than amnestic patients. LvPPA patients had left-lateralized WM degeneration; PCA patients had reductions in connections to bilateral posterior parietal, occipital, and temporal areas. Topological analysis showed the nonamnestic but not the amnestic group had more connected components than controls, indicating persistently lower connectivity. Longer disease duration and cognitive impairment were associated with more connected components and fewer cycles in individuals' brain graphs. Discussion: We have previously reported syndromic differences in GM degeneration and tau accumulation between AD syndromes; here we find corresponding differences in WM tracts connecting syndrome-specific epicenters. Determining the reasons for selective WM degeneration in nonamnestic AD is a research priority that will require integration of knowledge from neuroimaging, biomarker, autopsy, and functional genetic studies. Furthermore, longitudinal studies to determine the chronology of WM vs. GM degeneration will be key to assessing evidence for WM-mediated tau spread. [ABSTRACT FROM AUTHOR]

Published

2024

6. Exploring white matter dynamics and morphology through interactive numerical phantoms: the White Matter Generator

Author

Sidsel Winther, Oscar Peulicke, Mariam Andersson, Hans M. Kjer, Jakob A. Bærentzen, and Tim B. Dyrby

Subjects

diffusion MRI (dMRI), white matter (WM), numerical phantom, Monte Carlo simulations, microstructure imaging, interactive, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Brain white matter is a dynamic environment that continuously adapts and reorganizes in response to stimuli and pathological changes. Glial cells, especially, play a key role in tissue repair, inflammation modulation, and neural recovery. The movements of glial cells and changes in their concentrations can influence the surrounding axon morphology. We introduce the White Matter Generator (WMG) tool to enable the study of how axon morphology is influenced through such dynamical processes, and how this, in turn, influences the diffusion-weighted MRI signal. This is made possible by allowing interactive changes to the configuration of the phantom generation throughout the optimization process. The phantoms can consist of myelinated axons, unmyelinated axons, and cell clusters, separated by extra-cellular space. Due to morphological flexibility and computational advantages during the optimization, the tool uses ellipsoids as building blocks for all structures; chains of ellipsoids for axons, and individual ellipsoids for cell clusters. After optimization, the ellipsoid representation can be converted to a mesh representation which can be employed in Monte-Carlo diffusion simulations. This offers an effective method for evaluating tissue microstructure models for diffusion-weighted MRI in controlled bio-mimicking white matter environments. Hence, the WMG offers valuable insights into white matter's adaptive nature and implications for diffusion-weighted MRI microstructure models, and thereby holds the potential to advance clinical diagnosis, treatment, and rehabilitation strategies for various neurological disorders and injuries.

Published

2024

7. White matter microstructure, traumatic brain injury, and disruptive behavior disorders in girls and boys

Author

Guido I. Guberman, Guillaume Theaud, Samuel W. Hawes, Alain Ptito, Maxime Descoteaux, and Sheilagh Hodgins

Subjects

traumatic brain injury, diffusion MRI (dMRI), tractometry, behavior problems, multivariate analysis, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

IntroductionGirls and boys presenting disruptive behavior disorders (DBDs) display differences in white matter microstructure (WMM) relative to typically developing (TD) sex-matched peers. Boys with DBDs are at increased risk for traumatic brain injuries (TBIs), which are also known to impact WMM. This study aimed to disentangle associations of WMM with DBDs and TBIs.MethodsThe sample included 673 children with DBDs and 836 TD children, aged 9–10, from the Adolescent Brain Cognitive Development Study. Thirteen white matter bundles previously associated with DBDs were the focus of study. Analyses were undertaken separately by sex, adjusting for callous-unemotional traits (CU), attention-deficit hyperactivity disorder (ADHD), age, pubertal stage, IQ, ethnicity, and family income.ResultsAmong children without TBIs, those with DBDs showed sex-specific differences in WMM of several tracts relative to TD. Most differences were associated with ADHD, CU, or both. Greater proportions of girls and boys with DBDs than sex-matched TD children had sustained TBIs. Among girls and boys with DBDs, those who had sustained TBIs compared to those not injured, displayed WMM alterations that were robust to adjustment for all covariates. Across most DBD/TD comparisons, axonal density scores were higher among children presenting DBDs.DiscussionIn conclusion, in this community sample of children, those with DBDs were more likely to have sustained TBIs that were associated with additional, sex-specific, alterations of WMM. These additional alterations further compromise the future development of children with DBDs.

Published

2024

8. Greater white matter degeneration and lower structural connectivity in non-amnestic vs. amnestic Alzheimer’s disease

Author

Jeffrey S. Phillips, Nagesh Adluru, Moo K. Chung, Hamsanandini Radhakrishnan, Christopher A. Olm, Philip A. Cook, James C. Gee, Katheryn A. Q. Cousins, Sanaz Arezoumandan, David A. Wolk, Corey T. McMillan, Murray Grossman, and David J. Irwin

Subjects

diffusion MRI (dMRI), non-amnestic Alzheimer’s disease, logopenic variant of primary progressive aphasia (lvPPA), posterior cortical atrophy (PCA), corticobasal syndrome (CBS), behavioral variant Alzheimer’s disease, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

IntroductionMultimodal evidence indicates Alzheimer’s disease (AD) is characterized by early white matter (WM) changes that precede overt cognitive impairment. WM changes have overwhelmingly been investigated in typical, amnestic mild cognitive impairment and AD; fewer studies have addressed WM change in atypical, non-amnestic syndromes. We hypothesized each non-amnestic AD syndrome would exhibit WM differences from amnestic and other non-amnestic syndromes.Materials and methodsParticipants included 45 cognitively normal (CN) individuals; 41 amnestic AD patients; and 67 patients with non-amnestic AD syndromes including logopenic-variant primary progressive aphasia (lvPPA, n = 32), posterior cortical atrophy (PCA, n = 17), behavioral variant AD (bvAD, n = 10), and corticobasal syndrome (CBS, n = 8). All had T1-weighted MRI and 30-direction diffusion-weighted imaging (DWI). We performed whole-brain deterministic tractography between 148 cortical and subcortical regions; connection strength was quantified by tractwise mean generalized fractional anisotropy. Regression models assessed effects of group and phenotype as well as associations with grey matter volume. Topological analyses assessed differences in persistent homology (numbers of graph components and cycles). Additionally, we tested associations of topological metrics with global cognition, disease duration, and DWI microstructural metrics.ResultsBoth amnestic and non-amnestic patients exhibited lower WM connection strength than CN participants in corpus callosum, cingulum, and inferior and superior longitudinal fasciculi. Overall, non-amnestic patients had more WM disease than amnestic patients. LvPPA patients had left-lateralized WM degeneration; PCA patients had reductions in connections to bilateral posterior parietal, occipital, and temporal areas. Topological analysis showed the non-amnestic but not the amnestic group had more connected components than controls, indicating persistently lower connectivity. Longer disease duration and cognitive impairment were associated with more connected components and fewer cycles in individuals’ brain graphs.DiscussionWe have previously reported syndromic differences in GM degeneration and tau accumulation between AD syndromes; here we find corresponding differences in WM tracts connecting syndrome-specific epicenters. Determining the reasons for selective WM degeneration in non-amnestic AD is a research priority that will require integration of knowledge from neuroimaging, biomarker, autopsy, and functional genetic studies. Furthermore, longitudinal studies to determine the chronology of WM vs. GM degeneration will be key to assessing evidence for WM-mediated tau spread.

Published

2024

9. Artificial intelligence for diffusion MRI-based tissue microstructure estimation in the human brain: an overview.

Author

Faiyaz, Abrar, Doyley, Marvin M., Schifitto, Giovanni, and Uddin, Md Nasir

Subjects

ARTIFICIAL intelligence, DIFFUSION magnetic resonance imaging, IMAGE reconstruction, MICROSTRUCTURE

Abstract

Artificial intelligence (AI) has made significant advances in the field of diffusion magnetic resonance imaging (dMRI) and other neuroimaging modalities. These techniques have been applied to various areas such as image reconstruction, denoising, detecting and removing artifacts, segmentation, tissue microstructure modeling, brain connectivity analysis, and diagnosis support. State-of-the-art AI algorithms have the potential to leverage optimization techniques in dMRI to advance sensitivity and inference through biophysical models. While the use of AI in brain microstructures has the potential to revolutionize the way we study the brain and understand brain disorders, we need to be aware of the pitfalls and emerging best practices that can further advance this field. Additionally, since dMRI scans rely on sampling of the q-space geometry, it leaves room for creativity in data engineering in such a way that it maximizes the prior inference. Utilization of the inherent geometry has been shown to improve general inference quality and might be more reliable in identifying pathological differences. We acknowledge and classify AI-based approaches for dMRI using these unifying characteristics. This article also highlighted and reviewed general practices and pitfalls involving tissue microstructure estimation through data-driven techniques and provided directions for building on them. [ABSTRACT FROM AUTHOR]

Published

2023

10. Artificial intelligence for diffusion MRI-based tissue microstructure estimation in the human brain: an overview

Author

Abrar Faiyaz, Marvin M. Doyley, Giovanni Schifitto, and Md Nasir Uddin

Subjects

artificial intelligence, machine learning, deep learning, diffusion MRI (dMRI), neuroimaging, brain, Neurology. Diseases of the nervous system, RC346-429

Abstract

Artificial intelligence (AI) has made significant advances in the field of diffusion magnetic resonance imaging (dMRI) and other neuroimaging modalities. These techniques have been applied to various areas such as image reconstruction, denoising, detecting and removing artifacts, segmentation, tissue microstructure modeling, brain connectivity analysis, and diagnosis support. State-of-the-art AI algorithms have the potential to leverage optimization techniques in dMRI to advance sensitivity and inference through biophysical models. While the use of AI in brain microstructures has the potential to revolutionize the way we study the brain and understand brain disorders, we need to be aware of the pitfalls and emerging best practices that can further advance this field. Additionally, since dMRI scans rely on sampling of the q-space geometry, it leaves room for creativity in data engineering in such a way that it maximizes the prior inference. Utilization of the inherent geometry has been shown to improve general inference quality and might be more reliable in identifying pathological differences. We acknowledge and classify AI-based approaches for dMRI using these unifying characteristics. This article also highlighted and reviewed general practices and pitfalls involving tissue microstructure estimation through data-driven techniques and provided directions for building on them.

Published

2023

11. Editorial: Is two better than one? Exploring tissue microstructure with multi-modal imaging: Quantitative MRI and beyond

Author

Alberto De Luca, Kurt G. Schilling, and Andrada Ianus

Subjects

multi-modal imaging, tissue microstructure, quantitative MRI (qMRI), diffusion MRI (dMRI), PET-MR imaging, biophysical tissue models, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2023

12. Early structural connectivity within the sensorimotor network: Deviations related to prematurity and association to neurodevelopmental outcome.

Author

Neumane, Sara, Gondova, Andrea, Leprince, Yann, Hertz-Pannier, Lucie, Tomoki Arichi, and Dubois, Jessica

Subjects

LARGE-scale brain networks, DIFFUSION tensor imaging, DIFFUSION magnetic resonance imaging, CORPUS striatum, NEURAL development

Abstract

Consisting of distributed and interconnected structures that interact through cortico-cortical connections and cortico-subcortical loops, the sensorimotor (SM) network undergoes rapid maturation during the perinatal period and is thus particularly vulnerable to preterm birth. However, the impact of prematurity on the development and integrity of the emerging SM connections and their relationship to later motor and global impairments are still poorly understood. In this study we aimed to explore to which extent the early microstructural maturation of SM white matter (WM) connections at term-equivalent age (TEA) is modulated by prematurity and related with neurodevelopmental outcome at 18 months corrected age. We analyzed 118 diffusion MRI datasets from the developing Human Connectome Project (dHCP) database: 59 preterm (PT) low-risk infants scanned near TEA and a control group of full-term (FT) neonates paired for age at MRI and sex. We delineated WM connections between the primary SM cortices (S1, M1 and paracentral region) and subcortical structures using probabilistic tractography, and evaluated their microstructure with diffusion tensor imaging (DTI) and neurite orientation dispersion and density imaging (NODDI) models. To go beyond tract-specific univariate analyses, we computed a maturational distance related to prematurity based on the multi-parametric Mahalanobis distance of each PT infant relative to the FT group. Our results confirmed the presence of microstructural differences in SM tracts between PT and FT infants, with effects increasing with lower gestational age at birth. Maturational distance analyses highlighted that prematurity has a differential effect on SM tracts with higher distances and thus impact on (i) cortico-cortical than cortico-subcortical connections; (ii) projections involving S1 than M1 and paracentral region; and (iii) the most rostral cortico-subcortical tracts, involving the lenticular nucleus. These different alterations at TEA suggested that vulnerability follows a specific pattern coherent with the established WM caudo-rostral progression of maturation. Finally, we highlighted some relationships between NODDI-derived maturational distances of specific tracts and fine motor and cognitive outcomes at 18 months. As a whole, our results expand understanding of the significant impact of premature birth and early alterations on the emerging SM network even in low-risk infants, with possible relationship with neurodevelopmental outcomes. This encourages further exploration of these potential neuroimaging markers for prediction of neurodevelopmental disorders, with special interest for subtle neuromotor impairments frequently observed in preterm-born children. [ABSTRACT FROM AUTHOR]

Published

2022

13. Age-dependent microstructure alterations in 5xFAD mice by high-resolution diffusion tensor imaging.

Author

Maharjan, Surendra, Tsai, Andy P., Lin, Peter B., Ingraham, Cynthia, Jewett, Megan R., Landreth, Gary E., Oblak, Adrian L., and Nian Wang

Subjects

DIFFUSION tensor imaging, ECHO-planar imaging, DIFFUSION magnetic resonance imaging, THREE-dimensional imaging, CORPUS callosum

Abstract

Purpose: To evaluate the age-dependent microstructure changes in 5xFAD mice using high-resolution diffusion tensor imaging (DTI). Methods: The 5xFAD mice at 4, 7.5, and 12 months and the wild-type controls at 4 months were scanned at 9.4T using a 3D echo-planar imaging (EPI) pulse sequence with the isotropic spatial resolution of 100 μm. The b-value was 3000 s/mm² for all the diffusion MRI scans. The samples were also acquired with a gradient echo pulse sequence at 50 μm isotropic resolution. The microstructure changes were quantified with DTI metrics, including fractional anisotropy (FA) and mean diffusivity (MD). The conventional histology was performed to validate with MRI findings. Results: The FA values (p = 0.028) showed significant differences in the cortex between wild-type (WT) and 5xFAD mice at 4 months, while hippocampus, anterior commissure, corpus callosum, and fornix showed no significant differences for either FA and MD. FA values of 5xFAD mice gradually decreased in cortex (0.140 ± 0.007 at 4 months, 0.132 ± 0.008 at 7.5 months, 0.126 ± 0.013 at 12 months) and fornix (0.140 ± 0.007 at 4 months, 0.132 ± 0.008 at 7.5 months, 0.126 ± 0.013 at 12 months) with aging. Both FA (p = 0.029) and MD (p = 0.037) demonstrated significant differences in corpus callosum between 4 and 12 months age old. FA and MD were not significantly different in the hippocampus or anterior commissure. The age-dependent microstructure alterations were better captured by FA when compared to MD. Conclusion: FA showed higher sensitivity to monitor amyloid deposition in 5xFAD mice. DTI may be utilized as a sensitive biomarker to monitor betaamyloid progression for preclinical studies. [ABSTRACT FROM AUTHOR]

Published

2022

14. Impact of truncating diffusion MRI scans on diffusional kurtosis imaging.

Author

Fouto AR, Henriques RN, Golub M, Freitas AC, Ruiz-Tagle A, Esteves I, Gil-Gouveia R, Silva NA, Vilela P, Figueiredo P, and Nunes RG

Subjects

Humans, Female, Adult, Anisotropy, Computer Simulation, Signal-To-Noise Ratio, Reproducibility of Results, Image Interpretation, Computer-Assisted methods, Diffusion Tensor Imaging methods, Image Processing, Computer-Assisted methods, Healthy Volunteers, Diffusion Magnetic Resonance Imaging methods, Brain diagnostic imaging, Algorithms

Abstract

Objective: Diffusional kurtosis imaging (DKI) extends diffusion tensor imaging (DTI), characterizing non-Gaussian diffusion effects but requires longer acquisition times. To ensure the robustness of DKI parameters, data acquisition ordering should be optimized allowing for scan interruptions or shortening. Three methodologies were used to examine how reduced diffusion MRI scans impact DKI histogram-metrics: 1) the electrostatic repulsion model (Opt EEM ); 2) spherical codes (Opt SC ); 3) random (Random TRUNC )., Materials and Methods: Pre-acquired diffusion multi-shell data from 14 female healthy volunteers (29±5 years) were used to generate reordered data. For each strategy, subsets containing different amounts of the full dataset were generated. The subsampling effects were assessed on histogram-based DKI metrics from tract-based spatial statistics (TBSS) skeletonized maps. To evaluate each subsampling method on simulated data at different SNRs and the influence of subsampling on in vivo data, we used a 3-way and 2-way repeated measures ANOVA, respectively., Results: Simulations showed that subsampling had different effects depending on DKI parameter, with fractional anisotropy the most stable (up to 5% error) and radial kurtosis the least stable (up to 26% error). Random TRUNC performed the worst while the others showed comparable results. Furthermore, the impact of subsampling varied across distinct histogram characteristics, the peak value the least affected (Opt EEM : up to 5% error; Opt SC : up to 7% error) and peak height (Opt EEM : up to 8% error; Opt SC : up to 11% error) the most affected., Conclusion: The impact of truncation depends on specific histogram-based DKI metrics. The use of a strategy for optimizing the acquisition order is advisable to improve DKI robustness to exam interruptions., (© 2024. The Author(s).)

Published

2024

15. Early structural connectivity within the sensorimotor network: Deviations related to prematurity and association to neurodevelopmental outcome

Author

Sara Neumane, Andrea Gondova, Yann Leprince, Lucie Hertz-Pannier, Tomoki Arichi, and Jessica Dubois

Subjects

brain development, tractography, diffusion MRI (dMRI), Diffusion Tensor Imaging (DTI), NODDI (neurite orientation dispersion and density imaging), multivariate Mahalanobis distance, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Consisting of distributed and interconnected structures that interact through cortico-cortical connections and cortico-subcortical loops, the sensorimotor (SM) network undergoes rapid maturation during the perinatal period and is thus particularly vulnerable to preterm birth. However, the impact of prematurity on the development and integrity of the emerging SM connections and their relationship to later motor and global impairments are still poorly understood. In this study we aimed to explore to which extent the early microstructural maturation of SM white matter (WM) connections at term-equivalent age (TEA) is modulated by prematurity and related with neurodevelopmental outcome at 18 months corrected age. We analyzed 118 diffusion MRI datasets from the developing Human Connectome Project (dHCP) database: 59 preterm (PT) low-risk infants scanned near TEA and a control group of full-term (FT) neonates paired for age at MRI and sex. We delineated WM connections between the primary SM cortices (S1, M1 and paracentral region) and subcortical structures using probabilistic tractography, and evaluated their microstructure with diffusion tensor imaging (DTI) and neurite orientation dispersion and density imaging (NODDI) models. To go beyond tract-specific univariate analyses, we computed a maturational distance related to prematurity based on the multi-parametric Mahalanobis distance of each PT infant relative to the FT group. Our results confirmed the presence of microstructural differences in SM tracts between PT and FT infants, with effects increasing with lower gestational age at birth. Maturational distance analyses highlighted that prematurity has a differential effect on SM tracts with higher distances and thus impact on (i) cortico-cortical than cortico-subcortical connections; (ii) projections involving S1 than M1 and paracentral region; and (iii) the most rostral cortico-subcortical tracts, involving the lenticular nucleus. These different alterations at TEA suggested that vulnerability follows a specific pattern coherent with the established WM caudo-rostral progression of maturation. Finally, we highlighted some relationships between NODDI-derived maturational distances of specific tracts and fine motor and cognitive outcomes at 18 months. As a whole, our results expand understanding of the significant impact of premature birth and early alterations on the emerging SM network even in low-risk infants, with possible relationship with neurodevelopmental outcomes. This encourages further exploration of these potential neuroimaging markers for prediction of neurodevelopmental disorders, with special interest for subtle neuromotor impairments frequently observed in preterm-born children.

Published

2022

16. Corrigendum: Age-dependent microstructure alterations in 5xFAD mice by high-resolution diffusion tensor imaging

Author

Surendra Maharjan, Andy P. Tsai, Peter B. Lin, Cynthia Ingraham, Megan R. Jewett, Gary E. Landreth, Adrian L. Oblak, and Nian Wang

Subjects

Alzheimer's disease, 5xFAD, MRI, DTI, diffusion MRI (dMRI), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2022

17. Age-dependent microstructure alterations in 5xFAD mice by high-resolution diffusion tensor imaging

Author

Surendra Maharjan, Andy P. Tsai, Peter B. Lin, Cynthia Ingraham, Megan R. Jewett, Gary E. Landreth, Adrian L. Oblak, and Nian Wang

Subjects

Alzheimer’s disease, 5xFAD, MRI, DTI, diffusion MRI (dMRI), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

PurposeTo evaluate the age-dependent microstructure changes in 5xFAD mice using high-resolution diffusion tensor imaging (DTI).MethodsThe 5xFAD mice at 4, 7.5, and 12 months and the wild-type controls at 4 months were scanned at 9.4T using a 3D echo-planar imaging (EPI) pulse sequence with the isotropic spatial resolution of 100 μm. The b-value was 3000 s/mm2 for all the diffusion MRI scans. The samples were also acquired with a gradient echo pulse sequence at 50 μm isotropic resolution. The microstructure changes were quantified with DTI metrics, including fractional anisotropy (FA) and mean diffusivity (MD). The conventional histology was performed to validate with MRI findings.ResultsThe FA values (p = 0.028) showed significant differences in the cortex between wild-type (WT) and 5xFAD mice at 4 months, while hippocampus, anterior commissure, corpus callosum, and fornix showed no significant differences for either FA and MD. FA values of 5xFAD mice gradually decreased in cortex (0.140 ± 0.007 at 4 months, 0.132 ± 0.008 at 7.5 months, 0.126 ± 0.013 at 12 months) and fornix (0.140 ± 0.007 at 4 months, 0.132 ± 0.008 at 7.5 months, 0.126 ± 0.013 at 12 months) with aging. Both FA (p = 0.029) and MD (p = 0.037) demonstrated significant differences in corpus callosum between 4 and 12 months age old. FA and MD were not significantly different in the hippocampus or anterior commissure. The age-dependent microstructure alterations were better captured by FA when compared to MD.ConclusionFA showed higher sensitivity to monitor amyloid deposition in 5xFAD mice. DTI may be utilized as a sensitive biomarker to monitor beta-amyloid progression for preclinical studies.

Published

2022

18. Editorial: Is two better than one? Exploring tissue microstructure with multi-modal imaging: Quantitative MRI and beyond.

Author

De Luca, Alberto, Schilling, Kurt G., and Ianus, Andrada

Subjects

MAGNETIC resonance imaging, DIFFUSION magnetic resonance imaging, MICROSTRUCTURE, TISSUES

Published

2023

19. Structural Connectivity of Human Inferior Colliculus Subdivisions Using in vivo and post mortem Diffusion MRI Tractography.

Author

Sitek, Kevin R., Calabrese, Evan, Johnson, G. Allan, Ghosh, Satrajit S., and Chandrasekaran, Bharath

Subjects

DIFFUSION magnetic resonance imaging, INFERIOR colliculus, DIFFUSION tensor imaging, EFFERENT pathways, NEURAL pathways

Abstract

Inferior colliculus (IC) is an obligatory station along the ascending auditory pathway that also has a high degree of top-down convergence via efferent pathways, making it a major computational hub. Animal models have attributed critical roles for the IC in in mediating auditory plasticity, egocentric selection, and noise exclusion. IC contains multiple functionally distinct subdivisions. These include a central nucleus that predominantly receives ascending inputs and external and dorsal nuclei that receive more heterogeneous inputs, including descending and multisensory connections. Subdivisions of human IC have been challenging to identify and quantify using standard brain imaging techniques such as MRI, and the connectivity of each of these subnuclei has not been identified in the human brain. In this study, we estimated the connectivity of human IC subdivisions with diffusion MRI (dMRI) tractography, using both anatomical-based seed analysis as well as unsupervised k -means clustering. We demonstrate sensitivity of tractography to overall IC connections in both high resolution post mortem and in vivo datasets. k -Means clustering of the IC streamlines in both the post mortem and in vivo datasets generally segregated streamlines based on their terminus beyond IC, such as brainstem, thalamus, or contralateral IC. Using fine-grained anatomical segmentations of the major IC subdivisions, the post mortem dataset exhibited unique connectivity patterns from each subdivision, including commissural connections through dorsal IC and lateral lemniscal connections to central and external IC. The subdivisions were less distinct in the context of in vivo connectivity, although lateral lemniscal connections were again highest to central and external IC. Overall, the unsupervised and anatomically driven methods provide converging evidence for distinct connectivity profiles for each of the IC subdivisions in both post mortem and in vivo datasets, suggesting that dMRI tractography with high quality data is sensitive to neural pathways involved in auditory processing as well as top-down control of incoming auditory information. [ABSTRACT FROM AUTHOR]

Published

2022

20. Structural Connectivity of Human Inferior Colliculus Subdivisions Using in vivo and post mortem Diffusion MRI Tractography

Author

Kevin R. Sitek, Evan Calabrese, G. Allan Johnson, Satrajit S. Ghosh, and Bharath Chandrasekaran

Subjects

inferior colliculus, diffusion MRI (dMRI), tractography, structural connectivity, human auditory brainstem, subcortical auditory pathway, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Inferior colliculus (IC) is an obligatory station along the ascending auditory pathway that also has a high degree of top-down convergence via efferent pathways, making it a major computational hub. Animal models have attributed critical roles for the IC in in mediating auditory plasticity, egocentric selection, and noise exclusion. IC contains multiple functionally distinct subdivisions. These include a central nucleus that predominantly receives ascending inputs and external and dorsal nuclei that receive more heterogeneous inputs, including descending and multisensory connections. Subdivisions of human IC have been challenging to identify and quantify using standard brain imaging techniques such as MRI, and the connectivity of each of these subnuclei has not been identified in the human brain. In this study, we estimated the connectivity of human IC subdivisions with diffusion MRI (dMRI) tractography, using both anatomical-based seed analysis as well as unsupervised k-means clustering. We demonstrate sensitivity of tractography to overall IC connections in both high resolution post mortem and in vivo datasets. k-Means clustering of the IC streamlines in both the post mortem and in vivo datasets generally segregated streamlines based on their terminus beyond IC, such as brainstem, thalamus, or contralateral IC. Using fine-grained anatomical segmentations of the major IC subdivisions, the post mortem dataset exhibited unique connectivity patterns from each subdivision, including commissural connections through dorsal IC and lateral lemniscal connections to central and external IC. The subdivisions were less distinct in the context of in vivo connectivity, although lateral lemniscal connections were again highest to central and external IC. Overall, the unsupervised and anatomically driven methods provide converging evidence for distinct connectivity profiles for each of the IC subdivisions in both post mortem and in vivo datasets, suggesting that dMRI tractography with high quality data is sensitive to neural pathways involved in auditory processing as well as top-down control of incoming auditory information.

Published

2022

21. Fixel-Based Analysis and Free Water Corrected DTI Evaluation of HIV-Associated Neurocognitive Disorders.

Author

Finkelstein, Alan, Faiyaz, Abrar, Weber, Miriam T., Qiu, Xing, Uddin, Md Nasir, Zhong, Jianhui, and Schifitto, Giovanni

Subjects

NEUROBEHAVIORAL disorders, DIFFUSION tensor imaging, COGNITION disorders, WATER analysis, TAU proteins

Abstract

Background: White matter (WM) damage is a consistent finding in HIV-infected (HIV+) individuals. Previous studies have evaluated WM fiber tract-specific brain regions in HIV-associated neurocognitive disorders (HAND) using diffusion tensor imaging (DTI). However, DTI might lack an accurate biological interpretation, and the technique suffers from several limitations. Fixel-based analysis (FBA) and free water corrected DTI (fwcDTI) have recently emerged as useful techniques to quantify abnormalities in WM. Here, we sought to evaluate FBA and fwcDTI metrics between HIV+ and healthy controls (HIV−) individuals. Using machine learning classifiers, we compared the specificity of both FBA and fwcDTI metrics in their ability to distinguish between individuals with and without cognitive impairment in HIV+ individuals. Methods: Forty-two HIV+ and 52 HIV– participants underwent MRI exam, clinical, and neuropsychological assessments. FBA metrics included fiber density (FD), fiber bundle cross section (FC), and fiber density and cross section (FDC). We also obtained fwcDTI metrics such as fractional anisotropy (FAT) and mean diffusivity (MDT). Tract-based spatial statistics (TBSS) was performed on FAT and MDT. We evaluated the correlations between MRI metrics with cognitive performance and blood markers, such as neurofilament light chain (NfL), and Tau protein. Four different binary classifiers were used to show the specificity of the MRI metrics for classifying cognitive impairment in HIV+ individuals. Results: Whole-brain FBA showed significant reductions (up to 15%) in various fiber bundles, specifically the cerebral peduncle, posterior limb of internal capsule, middle cerebellar peduncle, and superior corona radiata. TBSS of fwcDTI metrics revealed decreased FAT in HIV+ individuals compared to HIV– individuals in areas consistent with those observed in FBA, but these were not significant. Machine learning classifiers were consistently better able to distinguish between cognitively normal patients and those with cognitive impairment when using fixel-based metrics as input features as compared to fwcDTI metrics. Conclusion: Our findings lend support that FBA may serve as a potential in vivo biomarker for evaluating and monitoring axonal degeneration in HIV+ patients at risk for neurocognitive impairment. [ABSTRACT FROM AUTHOR]

Published

2021

22. Fixel-Based Analysis and Free Water Corrected DTI Evaluation of HIV-Associated Neurocognitive Disorders

Author

Alan Finkelstein, Abrar Faiyaz, Miriam T. Weber, Xing Qiu, Md Nasir Uddin, Jianhui Zhong, and Giovanni Schifitto

Subjects

HIV, diffusion MRI (dMRI), fixel-based analysis, free water imaging, machine learning, cognitive impairment, Neurology. Diseases of the nervous system, RC346-429

Abstract

Background: White matter (WM) damage is a consistent finding in HIV-infected (HIV+) individuals. Previous studies have evaluated WM fiber tract-specific brain regions in HIV-associated neurocognitive disorders (HAND) using diffusion tensor imaging (DTI). However, DTI might lack an accurate biological interpretation, and the technique suffers from several limitations. Fixel-based analysis (FBA) and free water corrected DTI (fwcDTI) have recently emerged as useful techniques to quantify abnormalities in WM. Here, we sought to evaluate FBA and fwcDTI metrics between HIV+ and healthy controls (HIV−) individuals. Using machine learning classifiers, we compared the specificity of both FBA and fwcDTI metrics in their ability to distinguish between individuals with and without cognitive impairment in HIV+ individuals.Methods: Forty-two HIV+ and 52 HIV– participants underwent MRI exam, clinical, and neuropsychological assessments. FBA metrics included fiber density (FD), fiber bundle cross section (FC), and fiber density and cross section (FDC). We also obtained fwcDTI metrics such as fractional anisotropy (FAT) and mean diffusivity (MDT). Tract-based spatial statistics (TBSS) was performed on FAT and MDT. We evaluated the correlations between MRI metrics with cognitive performance and blood markers, such as neurofilament light chain (NfL), and Tau protein. Four different binary classifiers were used to show the specificity of the MRI metrics for classifying cognitive impairment in HIV+ individuals.Results: Whole-brain FBA showed significant reductions (up to 15%) in various fiber bundles, specifically the cerebral peduncle, posterior limb of internal capsule, middle cerebellar peduncle, and superior corona radiata. TBSS of fwcDTI metrics revealed decreased FAT in HIV+ individuals compared to HIV– individuals in areas consistent with those observed in FBA, but these were not significant. Machine learning classifiers were consistently better able to distinguish between cognitively normal patients and those with cognitive impairment when using fixel-based metrics as input features as compared to fwcDTI metrics.Conclusion: Our findings lend support that FBA may serve as a potential in vivo biomarker for evaluating and monitoring axonal degeneration in HIV+ patients at risk for neurocognitive impairment.

Published

2021

23. Diffusion MRI Spatial Super-Resolution Using Generative Adversarial Networks

Author

Albay, Enes, Demir, Ugur, Unal, Gozde, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Rekik, Islem, editor, Unal, Gozde, editor, Adeli, Ehsan, editor, and Park, Sang Hyun, editor

Published

2018

24. Using Multiple Diffusion MRI Measures to Predict Alzheimer’s Disease with a TV-L1 Prior

Author

for the Alzheimer’s Disease Neuroimaging Initiative (ADNI), Villalon-Reina, Julio E., Nir, Talia M., Gutman, Boris A., Jahanshad, Neda, Jack, Clifford R., Jr, Weiner, Michael W., Pasternak, Ofer, Thompson, Paul M., Hege, Hans-Christian, Series editor, Hoffman, David, Series editor, Polthier, Konrad, Series editor, Rumpf, Martin, Series editor, Fuster, Andrea, editor, Ghosh, Aurobrata, editor, Kaden, Enrico, editor, Rathi, Yogesh, editor, and Reisert, Marco, editor

Published

2017

25. An Open-Source Tool for Anisotropic Radiation Therapy Planning in Neuro-oncology Using DW-MRI Tractography

Author

Kesshi Jordan, Olivier Morin, Michael Wahl, Bagrat Amirbekian, Christopher Chapman, Julia Owen, Pratik Mukherjee, Steve Braunstein, and Roland Henry

Subjects

tractography, glioma, code:Python, neuro oncology, radiation therapy (radiotherapy), diffusion MRI (dMRI), Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

There is evidence from histopathological studies that glioma tumor cells migrate preferentially along large white matter bundles. If the peritumoral white matter structures can be used to predict the likely trajectory of migrating tumor cells outside of the surgical margin, then this information could be used to inform the delineation of radiation therapy (RT) targets. In theory, an anisotropic expansion that takes large white matter bundle anatomy into account may maximize the chances of treating migrating cancer cells and minimize the amount of brain tissue exposed to high doses of ionizing radiation. Diffusion-weighted MRI (DW-MRI) can be used in combination with fiber tracking algorithms to model the trajectory of large white matter pathways using the direction and magnitude of water movement in tissue. The method presented here is a tool for translating a DW-MRI fiber tracking (tractography) dataset into a white matter path length (WMPL) map that assigns each voxel the shortest distance along a streamline back to a specified region of interest (ROI). We present an open-source WMPL tool, implemented in the package Diffusion Imaging in Python (DIPY), and code to convert the resulting WMPL map to anisotropic contours for RT in a commercial treatment planning system. This proof-of-concept lays the groundwork for future studies to evaluate the clinical value of incorporating tractography modeling into treatment planning.

Published

2019

26. Diffusion Tensor Imaging Biomarkers to Predict Motor Outcomes in Stroke: A Narrative Review

Author

Luciana M. Moura, Rafael Luccas, Joselisa P. Q. de Paiva, Edson Amaro, Alexander Leemans, Claudia da C. Leite, Maria C. G. Otaduy, and Adriana B. Conforto

Subjects

diffusion MRI (dMRI), diffusion tensor imaging (DTI), corticospinal tract (CST), motor stroke, stroke recovery, white matter (WM), Neurology. Diseases of the nervous system, RC346-429

Abstract

Stroke is a leading cause of disability worldwide. Motor impairments occur in most of the patients with stroke in the acute phase and contribute substantially to disability. Diffusion tensor imaging (DTI) biomarkers such as fractional anisotropy (FA) measured at an early phase after stroke have emerged as potential predictors of motor recovery. In this narrative review, we: (1) review key concepts of diffusion MRI (dMRI); (2) present an overview of state-of-art methodological aspects of data collection, analysis and reporting; and (3) critically review challenges of DTI in stroke as well as results of studies that investigated the correlation between DTI metrics within the corticospinal tract and motor outcomes at different stages after stroke. We reviewed studies published between January, 2008 and December, 2018, that reported correlations between DTI metrics collected within the first 24 h (hyperacute), 2–7 days (acute), and >7–90 days (early subacute) after stroke. Nineteen studies were included. Our review shows that there is no consensus about gold standards for DTI data collection or processing. We found great methodological differences across studies that evaluated DTI metrics within the corticospinal tract. Despite heterogeneity in stroke lesions and analysis approaches, the majority of studies reported significant correlations between DTI biomarkers and motor impairments. It remains to be determined whether DTI results could enhance the predictive value of motor disability models based on clinical and neurophysiological variables.

Published

2019

27. Clinical Applications for Diffusion MRI and Tractography of Cranial Nerves Within the Posterior Fossa: A Systematic Review

Author

Jonathan Shapey, Sjoerd B. Vos, Tom Vercauteren, Robert Bradford, Shakeel R. Saeed, Sotirios Bisdas, and Sebastien Ourselin

Subjects

MRI—magnetic resonance imaging, diffusion MRI (dMRI), tractography, cranial nerves, brain tumors, trigeminal neuralgia (TN), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Objective: This paper presents a systematic review of diffusion MRI (dMRI) and tractography of cranial nerves within the posterior fossa. We assess the effectiveness of the diffusion imaging methods used and examine their clinical applications.Methods: The Pubmed, Web of Science and EMBASE databases were searched from January 1st 1997 to December 11th 2017 to identify relevant publications. Any study reporting the use of diffusion imaging and/or tractography in patients with confirmed cranial nerve pathology was eligible for selection. Study quality was assessed using the Methodological Index for Non-Randomized Studies (MINORS) tool.Results: We included 41 studies comprising 16 studies of patients with trigeminal neuralgia (TN), 22 studies of patients with a posterior fossa tumor and three studies of patients with other pathologies. Most acquisition protocols used single-shot echo planar imaging (88%) with a single b-value of 1,000 s/mm2 (78%) but there was significant variation in the number of gradient directions, in-plane resolution, and slice thickness between studies. dMRI of the trigeminal nerve generated interpretable data in all cases. Analysis of diffusivity measurements found significantly lower fractional anisotropy (FA) values within the root entry zone of nerves affected by TN and FA values were significantly lower in patients with multiple sclerosis. Diffusivity values within the trigeminal nerve correlate with the effectiveness of surgical treatment and there is some evidence that pre-operative measurements may be predictive of treatment outcome. Fiber tractography was performed in 30 studies (73%). Most studies evaluating fiber tractography involved patients with a vestibular schwannoma (82%) and focused on generating tractography of the facial nerve to assist with surgical planning. Deterministic tractography using diffusion tensor imaging was performed in 93% of cases but the reported success rate and accuracy of generating fiber tracts from the acquired diffusion data varied considerably.Conclusions: dMRI has the potential to inform our understanding of the microstructural changes that occur within the cranial nerves in various pathologies. Cranial nerve tractography is a promising technique but new avenues of using dMRI should be explored to optimize and improve its reliability.

Published

2019

28. An Open-Source Tool for Anisotropic Radiation Therapy Planning in Neuro-oncology Using DW-MRI Tractography.

Author

Jordan, Kesshi, Morin, Olivier, Wahl, Michael, Amirbekian, Bagrat, Chapman, Christopher, Owen, Julia, Mukherjee, Pratik, Braunstein, Steve, and Henry, Roland

Subjects

IONIZING radiation, TRACKING algorithms, DIFFUSION magnetic resonance imaging, WHITE matter (Nerve tissue), PYTHON programming language, GLIOMA treatment, CANCER radiotherapy, ANISOTROPY

Abstract

There is evidence from histopathological studies that glioma tumor cells migrate preferentially along large white matter bundles. If the peritumoral white matter structures can be used to predict the likely trajectory of migrating tumor cells outside of the surgical margin, then this information could be used to inform the delineation of radiation therapy (RT) targets. In theory, an anisotropic expansion that takes large white matter bundle anatomy into account may maximize the chances of treating migrating cancer cells and minimize the amount of brain tissue exposed to high doses of ionizing radiation. Diffusion-weighted MRI (DW-MRI) can be used in combination with fiber tracking algorithms to model the trajectory of large white matter pathways using the direction and magnitude of water movement in tissue. The method presented here is a tool for translating a DW-MRI fiber tracking (tractography) dataset into a white matter path length (WMPL) map that assigns each voxel the shortest distance along a streamline back to a specified region of interest (ROI). We present an open-source WMPL tool, implemented in the package Diffusion Imaging in Python (DIPY), and code to convert the resulting WMPL map to anisotropic contours for RT in a commercial treatment planning system. This proof-of-concept lays the groundwork for future studies to evaluate the clinical value of incorporating tractography modeling into treatment planning. [ABSTRACT FROM AUTHOR]

Published

2019

29. Diffusion Tensor Imaging Biomarkers to Predict Motor Outcomes in Stroke: A Narrative Review.

Author

Moura, Luciana M., Luccas, Rafael, Paiva, Joselisa P. Q. de, Amaro, Edson, Leemans, Alexander, Leite, Claudia da C., Otaduy, Maria C. G., and Conforto, Adriana B.

Subjects

BIOLOGICAL tags, DIFFUSION tensor imaging, STROKE, MAGNETIC resonance imaging, PYRAMIDAL tract

Abstract

Stroke is a leading cause of disability worldwide. Motor impairments occur in most of the patients with stroke in the acute phase and contribute substantially to disability. Diffusion tensor imaging (DTI) biomarkers such as fractional anisotropy (FA) measured at an early phase after stroke have emerged as potential predictors of motor recovery. In this narrative review, we: (1) review key concepts of diffusion MRI (dMRI); (2) present an overview of state-of-art methodological aspects of data collection, analysis and reporting; and (3) critically review challenges of DTI in stroke as well as results of studies that investigated the correlation between DTI metrics within the corticospinal tract and motor outcomes at different stages after stroke. We reviewed studies published between January, 2008 and December, 2018, that reported correlations between DTI metrics collected within the first 24 h (hyperacute), 2–7 days (acute), and >7–90 days (early subacute) after stroke. Nineteen studies were included. Our review shows that there is no consensus about gold standards for DTI data collection or processing. We found great methodological differences across studies that evaluated DTI metrics within the corticospinal tract. Despite heterogeneity in stroke lesions and analysis approaches, the majority of studies reported significant correlations between DTI biomarkers and motor impairments. It remains to be determined whether DTI results could enhance the predictive value of motor disability models based on clinical and neurophysiological variables. [ABSTRACT FROM AUTHOR]

Published

2019

30. Clinical Applications for Diffusion MRI and Tractography of Cranial Nerves Within the Posterior Fossa: A Systematic Review.

Author

Shapey, Jonathan, Vos, Sjoerd B., Vercauteren, Tom, Bradford, Robert, Saeed, Shakeel R., Bisdas, Sotirios, and Ourselin, Sebastien

Subjects

DIFFUSION magnetic resonance imaging, CRANIAL nerves, BRAIN tumor diagnosis, TRIGEMINAL neuralgia treatment, INFRATENTORIAL brain tumors

Abstract

Objective: This paper presents a systematic review of diffusion MRI (dMRI) and tractography of cranial nerves within the posterior fossa. We assess the effectiveness of the diffusion imaging methods used and examine their clinical applications. Methods: The Pubmed, Web of Science and EMBASE databases were searched from January 1st 1997 to December 11th 2017 to identify relevant publications. Any study reporting the use of diffusion imaging and/or tractography in patients with confirmed cranial nerve pathology was eligible for selection. Study quality was assessed using the Methodological Index for Non-Randomized Studies (MINORS) tool. Results: We included 41 studies comprising 16 studies of patients with trigeminal neuralgia (TN), 22 studies of patients with a posterior fossa tumor and three studies of patients with other pathologies. Most acquisition protocols used single-shot echo planar imaging (88%) with a single b-value of 1,000 s/mm2 (78%) but there was significant variation in the number of gradient directions, in-plane resolution, and slice thickness between studies. dMRI of the trigeminal nerve generated interpretable data in all cases. Analysis of diffusivity measurements found significantly lower fractional anisotropy (FA) values within the root entry zone of nerves affected by TN and FA values were significantly lower in patients with multiple sclerosis. Diffusivity values within the trigeminal nerve correlate with the effectiveness of surgical treatment and there is some evidence that pre-operative measurements may be predictive of treatment outcome. Fiber tractography was performed in 30 studies (73%). Most studies evaluating fiber tractography involved patients with a vestibular schwannoma (82%) and focused on generating tractography of the facial nerve to assist with surgical planning. Deterministic tractography using diffusion tensor imaging was performed in 93% of cases but the reported success rate and accuracy of generating fiber tracts from the acquired diffusion data varied considerably. Conclusions: dMRI has the potential to inform our understanding of the microstructural changes that occur within the cranial nerves in various pathologies. Cranial nerve tractography is a promising technique but new avenues of using dMRI should be explored to optimize and improve its reliability. [ABSTRACT FROM AUTHOR]

Published

2019

31. Brain microstructural and functional MRI: developments and application to a rat model of Alzheimer's disease

Author

Diao, Yujian, Gruetter, Rolf, and Jelescu, Ileana Ozana

Subjects

functional connectivity (FC), machine learning, resting-state functional MRI (rs-fMRI), glucose metabolism, Alzheimer's disease (AD), microstructure, diffusion MRI (dMRI), biomarker, biophysical modelling, streptozotocin (STZ)

Abstract

Magnetic resonance imaging (MRI) has been a valuable tool in investigating the pathological cascade of Alzheimer's disease (AD) and its progression, which are still open questions. Although some MRI-derived hallmarks in terms of functional connectivity and white matter degeneration have been revealed, the temporal involvement and interplay between them as well as other hallmarks such as amyloid load and neuronal density remain poorly understood. On the other hand, brain glucose hypometabolism is gradually taking center stage as a key player in the onset of AD, which had been described as a form of "type-3 diabetes". In this context, this thesis work presents a comprehensive study to characterize longitudinal changes in functional connectivity using resting-state functional MRI and microstructure using diffusion MRI, and to correlate them to glucose hypometabolism and neuronal density in a rat model of AD. This study is mainly focused on establishing an optimized image processing pipeline dedicated for rat fMRI data, optimizing a computational model of diffusion in white matter using a novel deep learning approach, and assessing the spatiotemporal relationships between biomarkers regarding to microstructure and function in the brain by using advanced statistical methods as well as state-of-the-art machine learning approaches in order to provide a comprehensive characterization of the pathological cascade and progression of neurodegeneration resulting from brain glucose metabolism disruption.

Published

2023

32. Corrigendum: Age-dependent microstructure alterations in 5xFAD mice by high-resolution diffusion tensor imaging.

Subjects

DIFFUSION tensor imaging, DIFFUSION magnetic resonance imaging, MICE, MICROSTRUCTURE, ALZHEIMER'S disease

Published

2022

33. Characterization of the transition between healthy states using spatial and temporal correlations of the cerebral functional MRI (fMRI) and diffusion MRI (dMRI) signals

Author

Sánchez, Stella Maris and Villarreal, Mirta Fabiana

Subjects

ALZHEIMER'S DISEASE, DIFFUSION MRI (dMRI), IMAGENES DE DIFUSION POR RESONANCIA MAGNETICA (dMRI), WHITE MATTER MICROSTRUCTURE, FUNCTIONAL MRI (fMRI), MICROESTRUCTURA DE SUSTANCIA BLANCA, ENFERMEDAD DE ALZHEIMER, CONECTIVIDAD CEREBRAL, BRAIN CONNECTIVITY, IMAGENES FUNCIONALES POR RESONANCIA MAGNETICA (fMRI)

Abstract

Caracterizar el funcionamiento y la estructura del cerebro humano conforma uno de los desafíos más interesantes desde tiempos inmemoriales. Entender sus posibles estados y alteraciones a partir de las bases del conocimiento presenta infinidad de obstáculos, algunos de los cuales han podido sortearse. Los avances en materia científica y tecnológica del siglo XX, permitieron un abordaje prometedor en este campo, siendo sin lugar a dudas la técnica de imágenes por resonancia magnética nuclear (MRI) la más prometedora para el estudio del cerebro, constituyendo un claro ejemplo del alcance de la Física a otras disciplinas, como lo es la Medicina. Este tipo de métodos tienen un rol fundamental en los estudios interdisciplinarios ya que empujan constantemente los límites de la ciencia y la tecnología. El principal objetivo de esta Tesis es implementar técnicas de imágenes de difusión de MRI (dMRI) e imágenes funcionales en estado de reposo (fMRI) para evaluar posibles anomalías presentes en la microestructura de fibras nerviosas de sustancia blanca, y en las conectividades funcional y estructural en personas en riesgo genético de padecer la enfermedad de Alzheimer (AD). Con este propósito, se expandieron las métricas ya conocidas para fMRI y dMRI de modo tal de definir posibles predictores de la enfermedad. Para llevarlo a cabo, se ha explorado una muestra de sujetos adultos cognitivamente asintomáticos, pero con antecedentes de la AD en familiares de primer grado, mediante diversas metodologías. Se ha estudiado la arquitectura de las vías que conectan las áreas cerebrales que se ven primeramente afectadas durante la enfermedad mediante el análisis de dMRI. Se caracterizaron también la conectividad funcional y estructural de esta muestra de sujetos y se las comparó con la de un grupo de personas demográficamente equiparables pero sin antecedentes familiares de AD. Además, se asociaron estos aspectos con variables comportamentales y con la morfología de regiones cerebrales de especial interés para la enfermedad. Por último, se buscó construir una métrica que cuantifique el acoplamiento entre las dos conectividades previamente obtenidas, funcional y estructural. Las técnicas puestas a prueba para el estudio de la sustancia blanca han revelado una alteración en su integridad en el grupo de estudio en comparación al grupo control. Este deterioro se observó en la región posterior del cuerpo calloso, un gran haz de fibras que conecta transversalmente los dos hemisferios cerebrales, y una pequeña porción del fórnix derecho. Llamativamente, las conexiones que forman parte de este sector deteriorado de sustancia blanca involucran regiones que se ven afectadas por la AD. Por su parte, se hallaron también diferencias en la conectividad funcional obtenida a partir de la corteza entorrinal, viéndose disminuida en el grupo con antecedentes familiares de AD. Sin embargo, no se encontraron diferencias significativas en la conectividad funcional a partir de los núcleos talámicos anterodorsales ni en la conectividad estructural global. Finalmente, se logró una métrica que describe el acoplamiento de las conectividades en distintos enfoques: por grupo de estudio, por región de interés y por pares de conexión. Para este último caso se han encontrado no solo pares de conexión de regiones cuyo acoplamiento de conectividades es estadísticamente diferente entre grupos, sino también conexiones con acoplamiento significativo en el grupo control y no en el grupo asociado a la AD, marcando una potencial deficiencia. Replicar los resultados aquí presentados en otras muestras similares de sujetos con antecedentes familiares de primer orden podría resultar en importantes implicancias para la definición de la conectividad cerebral en estadios tempranos de la AD. Characterizing the function and structure of the human brain is one of Mankind’s most interesting challenges. Understanding its states and alterations present a number of obstacles, some of which are being already overcome. The advances in scientific and technological matters of the 20th century allowed a promising approach in this field, being doubtless the nuclear magnetic resonance imaging (MRI) technique the most promising for the study of the brain, constituting a clear example of the scope from Physics to other disciplines, such as Medicine. These types of methods play a key role in interdisciplinary studies since they constantly push the limits of science and technology. The main objective of this Thesis is implementing diffusion MRI (dMRI) and functional MRI (fMRI) techniques to assess anomalies present in the microstructure of white matter fiber nerves, and structural and functional connectivity, in persons who are at risk of developing late-onset Alzheimer’s Disease (AD). With this purpose, we have expanded known metrics of fMRI and dMRI data with the aim of quantifying predictors of AD. To achieve this, we studied a sample of middle-aged asymptomatic offspring of patients diagnosed with late-onset AD with diverse methodologies. We explored white matter architecture of pathways which connect brain regions that are firstly affected by AD, by processing dMRI data. We also obtained and compared functional and structural connectivity observations between the group of interest and a similar control group without family history of AD. In addition, we sought associations of structural and functional metrics with cognitive scores and morphologic grey matter measures. Lastly, we defined a coupling metric between structural and functional connectivity. The implemented techniques to study the white matter microstructure revealed a subtle alteration in the group of offspring of late-onset AD compared with the control group. This deterioration is presented in posterior corpus callosum and right fornix. Surprisingly, this abnormal white matter area involves connections between grey matter regions that are affected by AD in its initial stages. We found decreased functional connectivity from the entorhinal cortex in the experimental group compared with healthy persons without a family history of AD. However, we did not find any significant difference in the functional connectivity from anterodorsal thalamic nuclei, as described in neuropathological reports, nor in regards to global structural connectivity. Finally, we developed a metric which describes the coupling between connectivities in three approaches: per group, per region of interest, and per connection. In the latter case, we found not only pairs of brain regions with statistically significant coupling, but also connections that are significant only in the control group, which suggests a potential deficit in the middle-aged offspring of AD patients. If replicated, the present observations of functional and structural brain connectivity changes in cognitively normal persons with family history of AD may bear important implications for the definition, early diagnosis in early stages of the disease. Fil: Sánchez, Stella Maris. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina.

Published

2021

34. Leveraging genetic diversity in mice to inform individual differences in brain microstructure and memory.

Author

Murdy TJ, Dunn AR, Singh S, Telpoukhovskaia MA, Zhang S, White JK, Kahn I, Febo M, and Kaczorowski CC

Abstract

In human Alzheimer's disease (AD) patients and AD mouse models, both differential pre-disease brain features and differential disease-associated memory decline are observed, suggesting that certain neurological features may protect against AD-related cognitive decline. The combination of these features is known as brain reserve, and understanding the genetic underpinnings of brain reserve may advance AD treatment in genetically diverse human populations. One potential source of brain reserve is brain microstructure, which is genetically influenced and can be measured with diffusion MRI (dMRI). To investigate variation of dMRI metrics in pre-disease-onset, genetically diverse AD mouse models, we utilized a population of genetically distinct AD mice produced by crossing the 5XFAD transgenic mouse model of AD to 3 inbred strains (C57BL/6J, DBA/2J, FVB/NJ) and two wild-derived strains (CAST/EiJ, WSB/EiJ). At 3 months of age, these mice underwent diffusion magnetic resonance imaging (dMRI) to probe neural microanatomy in 83 regions of interest (ROIs). At 5 months of age, these mice underwent contextual fear conditioning (CFC). Strain had a significant effect on dMRI measures in most ROIs tested, while far fewer effects of sex, sex*strain interactions, or strain*sex*5XFAD genotype interactions were observed. A main effect of 5XFAD genotype was observed in only 1 ROI, suggesting that the 5XFAD transgene does not strongly disrupt neural development or microstructure of mice in early adulthood. Strain also explained the most variance in mouse baseline motor activity and long-term fear memory. Additionally, significant effects of sex and strain*sex interaction were observed on baseline motor activity, and significant strain*sex and sex*5XFAD genotype interactions were observed on long-term memory. We are the first to study the genetic influences of brain microanatomy in genetically diverse AD mice. Thus, we demonstrated that strain is the primary factor influencing brain microstructure in young adult AD mice and that neural development and early adult microstructure are not strongly altered by the 5XFAD transgene. We also demonstrated that strain, sex, and 5XFAD genotype interact to influence memory in genetically diverse adult mice. Our results support the usefulness of the 5XFAD mouse model and convey strong relationships between natural genetic variation, brain microstructure, and memory., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Murdy, Dunn, Singh, Telpoukhovskaia, Zhang, White, Kahn, Febo and Kaczorowski.)

Published

2023

35. Corrigendum: Age-dependent microstructure alterations in 5xFAD mice by high-resolution diffusion tensor imaging.

Author

Maharjan S, Tsai AP, Lin PB, Ingraham C, Jewett MR, Landreth GE, Oblak AL, and Wang N

Abstract

[This corrects the article DOI: 10.3389/fnins.2022.964654.]., (Copyright © 2022 Maharjan, Tsai, Lin, Ingraham, Jewett, Landreth, Oblak and Wang.)

Published

2022

36. White matter tracing combined with electric field simulation – A patient-specific approach for deep brain stimulation

Author

Nordin, Teresa, Zsigmond, Peter, Pujol, Sonia, Westin, Carl-Fredrik, Wårdell, Karin, Nordin, Teresa, Zsigmond, Peter, Pujol, Sonia, Westin, Carl-Fredrik, and Wårdell, Karin

Abstract

Objective Deep brain stimulation (DBS) in zona incerta (Zi) is used for symptom alleviation in essential tremor (ET). Zi is positioned along the dentato-rubro-thalamic tract (DRT). Electric field simulations with the finite element method (FEM) can be used for estimation of a volume where the stimulation affects the tissue by applying a fixed isolevel (VDBS). This work aims to develop a workflow for combined patient-specific electric field simulation and white matter tracing of the DRT, and to investigate the influence on the VDBS from different brain tissue models, lead design and stimulation modes. The novelty of this work lies in the combination of all these components. Method Patients with ET were implanted in Zi (lead 3389, n = 3, voltage mode; directional lead 6172, n = 1, current mode). Probabilistic reconstruction from diffusion MRI (dMRI) of the DRT (n = 8) was computed with FSL Toolbox. Brain tissue models were created for each patient (two homogenous, one heterogenous isotropic, one heterogenous anisotropic) and the respective VDBS (n = 48) calculated from the Comsol Multiphysics FEM simulations. The DRT and VDBS were visualized with 3DSlicer and superimposed on the preoperative T2 MRI, and the common volumes calculated. Dice Coefficient (DC) and level of anisotropy were used to evaluate and compare the brain models. Result Combined patient-specific tractography and electric field simulation was designed and evaluated, and all patients showed benefit from DBS. All VDBS overlapped the reconstructed DRT. Current stimulation showed prominent difference between the tissue models, where the homogenous grey matter deviated most (67 < DC < 69). Result from heterogenous isotropic and anisotropic models were similar (DC > 0.95), however the anisotropic model consistently generated larger volumes related to a greater extension of the electric field along the DBS lead. Independent of tissue model, the steering effect of the directional lead was evident and, Funding agencies: Swedish Foundation for Strategic ResearchSwedish Foundation for Strategic Research [SSF BD150032]; Swedish Research CouncilSwedish Research Council [VR 2016-03564]; National Institute of HealthUnited States Department of Health & Human ServicesNational In

Published

2019

37. White matter tracing combined with electric field simulation – A patient-specific approach for deep brain stimulation

Author

Teresa Nordin, Peter Zsigmond, Sonia Pujol, Carl-Fredrik Westin, and Karin Wårdell

Subjects

Male, Deep Brain Stimulation, Essential Tremor, Medical Laboratory and Measurements Technologies, Medical Engineering, Electrical conductivity tensor, lcsh:Computer applications to medicine. Medical informatics, behavioral disciplines and activities, lcsh:RC346-429, Thalamus, Dentato-rubro-thalamic tract (DRT), Humans, Gray Matter, Deep brain stimulation (DBS), lcsh:Neurology. Diseases of the nervous system, Medicinsk laboratorie- och mätteknik, Medicinteknik, Aged, Aged, 80 and over, Essential tremor (ET), Electric Conductivity, Zona Incerta (Zi), Regular Article, White Matter, nervous system diseases, surgical procedures, operative, Diffusion Tensor Imaging, nervous system, lcsh:R858-859.7, Anisotropy, Female, therapeutics, Tractography, Algorithms, Diffusion MRI (dMRI)

Abstract

Highlights • Novel workflow for combined tractography and patient-specific DBS simulations. • Accurate tissue segmentation is essential for DBS electric field simulation. • The tissue model is of higher importance for current controlled DBS. • Directional leads require a precise targeting to tailor the electric field. • DRT overlapped the isovolume in Zi for all patients., Objective Deep brain stimulation (DBS) in zona incerta (Zi) is used for symptom alleviation in essential tremor (ET). Zi is positioned along the dentato-rubro-thalamic tract (DRT). Electric field simulations with the finite element method (FEM) can be used for estimation of a volume where the stimulation affects the tissue by applying a fixed isolevel (VDBS). This work aims to develop a workflow for combined patient-specific electric field simulation and white matter tracing of the DRT, and to investigate the influence on the VDBS from different brain tissue models, lead design and stimulation modes. The novelty of this work lies in the combination of all these components. Method Patients with ET were implanted in Zi (lead 3389, n = 3, voltage mode; directional lead 6172, n = 1, current mode). Probabilistic reconstruction from diffusion MRI (dMRI) of the DRT (n = 8) was computed with FSL Toolbox. Brain tissue models were created for each patient (two homogenous, one heterogenous isotropic, one heterogenous anisotropic) and the respective VDBS (n = 48) calculated from the Comsol Multiphysics FEM simulations. The DRT and VDBS were visualized with 3DSlicer and superimposed on the preoperative T2 MRI, and the common volumes calculated. Dice Coefficient (DC) and level of anisotropy were used to evaluate and compare the brain models. Result Combined patient-specific tractography and electric field simulation was designed and evaluated, and all patients showed benefit from DBS. All VDBS overlapped the reconstructed DRT. Current stimulation showed prominent difference between the tissue models, where the homogenous grey matter deviated most (67 0.95), however the anisotropic model consistently generated larger volumes related to a greater extension of the electric field along the DBS lead. Independent of tissue model, the steering effect of the directional lead was evident and consistent. Conclusion A workflow for patient-specific electric field simulations in combination with reconstruction of DRT was successfully implemented. Accurate tissue classification is essential for electric field simulations, especially when using the current control stimulation. With an accurate targeting and tractography reconstruction, directional leads have the potential to tailor the electric field into the desired region.

Published

2019

38. Clinical Applications for Diffusion MRI and Tractography of Cranial Nerves Within the Posterior Fossa: A Systematic Review

Author

Jonathan, Shapey, Sjoerd B, Vos, Tom, Vercauteren, Robert, Bradford, Shakeel R, Saeed, Sotirios, Bisdas, and Sebastien, Ourselin

Subjects

trigeminal neuralgia (TN), diffusion MRI (dMRI), tractography, cranial nerves, brain tumors, MRI—magnetic resonance imaging, Systematic Review, Neuroscience

Abstract

Objective: This paper presents a systematic review of diffusion MRI (dMRI) and tractography of cranial nerves within the posterior fossa. We assess the effectiveness of the diffusion imaging methods used and examine their clinical applications. Methods: The Pubmed, Web of Science and EMBASE databases were searched from January 1st 1997 to December 11th 2017 to identify relevant publications. Any study reporting the use of diffusion imaging and/or tractography in patients with confirmed cranial nerve pathology was eligible for selection. Study quality was assessed using the Methodological Index for Non-Randomized Studies (MINORS) tool. Results: We included 41 studies comprising 16 studies of patients with trigeminal neuralgia (TN), 22 studies of patients with a posterior fossa tumor and three studies of patients with other pathologies. Most acquisition protocols used single-shot echo planar imaging (88%) with a single b-value of 1,000 s/mm2 (78%) but there was significant variation in the number of gradient directions, in-plane resolution, and slice thickness between studies. dMRI of the trigeminal nerve generated interpretable data in all cases. Analysis of diffusivity measurements found significantly lower fractional anisotropy (FA) values within the root entry zone of nerves affected by TN and FA values were significantly lower in patients with multiple sclerosis. Diffusivity values within the trigeminal nerve correlate with the effectiveness of surgical treatment and there is some evidence that pre-operative measurements may be predictive of treatment outcome. Fiber tractography was performed in 30 studies (73%). Most studies evaluating fiber tractography involved patients with a vestibular schwannoma (82%) and focused on generating tractography of the facial nerve to assist with surgical planning. Deterministic tractography using diffusion tensor imaging was performed in 93% of cases but the reported success rate and accuracy of generating fiber tracts from the acquired diffusion data varied considerably. Conclusions: dMRI has the potential to inform our understanding of the microstructural changes that occur within the cranial nerves in various pathologies. Cranial nerve tractography is a promising technique but new avenues of using dMRI should be explored to optimize and improve its reliability.

Published

2018

39. MR microscopy of neuronal tissue : acquisition acceleration, modelling and experimental validation of water diffusion

Author

Nguyen, van Khieu, Laboratoire d'Imagerie et de Spectroscopie (LRMN), Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Inria Saclay - Ile de France, Institut National de Recherche en Informatique et en Automatique (Inria), Université Paris Saclay (COmUE), Luisa Ciobanu, and Jing-Rebecca Li

Subjects

Diffusion, Échantillonnage clairsemé, Compressed sensing (CS), Modélisation, Modeling, [PHYS.PHYS.PHYS-MED-PH]Physics [physics]/Physics [physics]/Medical Physics [physics.med-ph], IRM de diffusion (IRMd), Agrégation limitée par la diffusion (DLA), Diffusion limited aggregation (DLA), Simulation, Diffusion MRI (dMRI)

Abstract

Compressed sensing (CS) exploits the compressibility of different types of images to reconstruct undersampled data without loss of information. The technique can be applied to MRI to reduce the acquisition times. The CS is based on three major components: (1) sparsity representation of the signal in some transform domain, (2) incoherent measurements, and (3) sparsity-constrained nonlinear reconstruction method. If the total number of points in the image is larger than four times the number of sparse coefficients, then the reconstruction of under sampled data is feasible. In the first results part of this thesis, we propose a new under sampling model based on the diffusion limited aggregation (DLA) theory and show that it performs better than the random variable under sampling method. The DLA under sampling model was used to implement the CS for T2-weighted and T1-weighted high resolution imaging at the ultra-high magnetic field (17.2T). In both cases, the acquisition time was reduced by 50% while maintaining the quality of the images in terms of spatial resolution, contrast to noise ratio, and signal intensity quantification. Both new CS pulse sequences (csRARE and csFLASH) were implemented in ParaVision 5.1 commercial software. The second results part of the thesis is focused on the study of the time-dependent diffusivity in the abdominal ganglion of Aplysia California. The Aplysia abdominal ganglion was chosen in this imaging study because high resolution MR imaging allows the fine anatomical description of the cellular network (size of individual neurons and orientation of axons). Using the Aplysia ganglia to study the relationship between the cellular structure and the diffusion MRI signal can shed light on this relationship for more complex organisms. We measured the dMRI signal at several diffusion times in the abdominal ganglion and performed simulations of water diffusion in geometries obtained after segmenting high resolution T2-weighted images and incorporating known information about the cellular structure from the literature. To match the dMRI signal in the single cell neurons with numerical simulations signal, the large cell outline was segmented from the anatomical T2 weighted image. Inside this cell shape, an irregularly shaped nucleus was manually generated (around 25-30% volume fraction). The small cells were modeled as small spheres with a smaller concentric spherical nucleus (around 25% volume fraction). The nerve was modeled by combining axons (cylinders) of different diameters consistent with the literature. The numerical dMRI signal can be simulated by solving Bloch-Torrey equation under the geometries domain described above. By fitting the experimental signal to the simulated signal for several types of cells such as: large cell neurons (diameter between 150 µm and 420 µm); cluster of small neuron cells gathered in the shape of a bag (up to 400 cells in adult Aplysia in each bag with cell size between 40 µm to 100 µm in diameter); and nerves (group of axons cylindrical shape diameter from less than 1 µm to 25 µm) at a wide range of diffusion times, we obtained estimates of the intrinsic diffusion coefficient in the nucleus and the cytoplasm (for cell neurons) and the intrinsic diffusion coefficient in the axons (for the nerves). We also evaluated the reliability of using an existing formula for the time-dependent diffusion coefficient to estimate cell size.; La technique d’acquisition comprimée ou compressed sensing (CS) exploite la compressibilité de différents types d’images pour reconstruire des données sous-échantillonnées sans perte d’informations. Cette technique peut être appliquée à l’IRM pour réduire les temps d’acquisition. CS est basée sur trois composantes majeures : (1) la représentation parcimonieuse du signal dans un domaine de transformation, (2) des mesures incohérentes et (3) une méthode de reconstruction non-linéaire avec une contrainte de parcimonie. Dans la première résultats partie de cette thèse, nous proposons un nouveau modèle de sous-échantillonnage basé sur la théorie de l’agrégation limitée par la diffusion (DLA) et montrons qu’il est plus performant que la méthode de sous-échantillonnage aléatoire. Le modèle de sous-échantillonnage DLA a été utilisé pour implémenter la technique de CS pour l’imagerie haute résolution pondérée T2 et T1 sur un champ magnétique très intense (17.2T). Pour chacune des pondérations, le temps d’acquisition a été réduit de 50% tout en conservant la qualité des images en termes de résolution spatiale, rapport contraste sur bruit et quantification de l’intensité du signal. Les deux nouvelles séquences d’impulsions CS (csRARE et csFLASH) ont été implémentées sur le logiciel commercial ParaVision 5.1. La seconde résultats partie de la thèse est centrée sur l’étude de la dépendance en temps de la diffusivité dans le ganglion abdominal de l’Aplysia Californica. Le ganglion abdominal de l’aplysie a été choisi pour cette étude d’imagerie car l’IRM à haute résolution permet la description anatomique fine du réseau cellulaire (taille des neurones individuels et orientation des axones). Utiliser les tissus neuronaux de l’aplysie pour étudier la relation entre la structure cellulaire et le signal d’IRM de diffusion peut permettre de comprendre cette relation pour des organismes plus complexes. Le signal d’IRM de diffusion (IRMd) a été mesuré à différents temps de diffusion dans le ganglion abdominal et des simulations de la diffusion de l’eau dans des géométries obtenues à partir de la segmentation d’images haute résolution pondérées T2 et l’incorporation d’informations sur la structure cellulaire trouvées dans la littérature ont été réalisées. Pour comparer le signal d’IRMd dans des neurones composés d’une seule cellule avec le signal des simulations numériques, des cellules de grande taille ont été segmentées à partir d’images anatomiques pondérées T2. A l’intérieur des cellules, un noyau à forme irrégulière a été généré manuellement (environ 25-30% en fraction volumique). Les petites cellules ont été modélisées comme des petites sphères avec un petit noyau sphérique concentrique (environ 25% en fraction volumique). Le nerf a été modélisé en combinant des axones (cylindres) de différents diamètres en cohérence avec la littérature. Le signal numérique d’IRMd a été simulé en résolvant l’équation de Bloch-Torrey pour les domaines géométriques décris ci-dessus. En fittant le signal expérimental avec le signal simulé pour différents types de cellules comme les grandes cellules neuronales (diamètre entre 150 et 420 µm), des agrégats de petites cellules neuronales ayant la forme d’un sac (jusqu’à 400 cellule chez l’aplysie adulte dans chaque sac avec une taille cellulaire entre 40 et 100 µm de diamètre), des nerfs (groupes d’axones de forme cylindrique avec un diamètre de moins de 1 à 25 µm) pour une grande gamme de temps de diffusions, nous avons obtenu des estimations du coefficient de diffusion intrinsèque dans le noyau et le cytoplasme (pour les neurones) et le coefficient de diffusion intrinsèque dans les axones (pour les nerfs). Nous avons aussi évalué la pertinence d’utiliser une formule préexistante décrivant la dépendance en temps du coefficient de diffusion pour estimer la taille des cellules.

Published

2017

40. Diffusion tensor imaging biomarkers to predict motor outcomes in stroke : A narrative review

Author

Joselisa Péres Queiroz de Paiva, Claudia da Costa Leite, Maria Concepcion Garcia Otaduy, Adriana Bastos Conforto, Rafael Luccas, Edson Amaro, Alexander Leemans, and Luciana Monteiro Moura

Subjects

medicine.medical_specialty, Diffusion tensor imaging (DTI), Neurology, Corticospinal tract (CST), medicine.medical_treatment, Clinical Neurology, Review, lcsh:RC346-429, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Fractional anisotropy, medicine, Stroke recovery, Stroke, lcsh:Neurology. Diseases of the nervous system, business.industry, White matter (WM), medicine.disease, Motor stroke, Corticospinal tract, Narrative review, Neurology (clinical), Early phase, business, 030217 neurology & neurosurgery, Diffusion MRI, Diffusion MRI (dMRI)

Abstract

Stroke is a leading cause of disability worldwide. Motor impairments occur in most of the patients with stroke in the acute phase and contribute substantially to disability. Diffusion tensor imaging (DTI) biomarkers such as fractional anisotropy (FA) measured at an early phase after stroke have emerged as potential predictors of motor recovery. In this narrative review, we: (1) review key concepts of diffusion MRI (dMRI); (2) present an overview of state-of-art methodological aspects of data collection, analysis and reporting; and (3) critically review challenges of DTI in stroke as well as results of studies that investigated the correlation between DTI metrics within the corticospinal tract and motor outcomes at different stages after stroke. We reviewed studies published between January, 2008 and December, 2018, that reported correlations between DTI metrics collected within the first 24 h (hyperacute), 2–7 days (acute), and >7–90 days (early subacute) after stroke. Nineteen studies were included. Our review shows that there is no consensus about gold standards for DTI data collection or processing. We found great methodological differences across studies that evaluated DTI metrics within the corticospinal tract. Despite heterogeneity in stroke lesions and analysis approaches, the majority of studies reported significant correlations between DTI biomarkers and motor impairments. It remains to be determined whether DTI results could enhance the predictive value of motor disability models based on clinical and neurophysiological variables.

Published

2019

41. Visualization and Processing of Higher Order Descriptors for Multi-Valued Data (Dagstuhl Seminar 14082)

Author

Bernhard Burgeth and Ingrid Hotz and Anna Vilanova Bartroli and Carl-Fredrik Westin, Burgeth, Bernhard, Hotz, Ingrid, Vilanova Bartroli, Anna, Westin, Carl-Fredrik, Bernhard Burgeth and Ingrid Hotz and Anna Vilanova Bartroli and Carl-Fredrik Westin, Burgeth, Bernhard, Hotz, Ingrid, Vilanova Bartroli, Anna, and Westin, Carl-Fredrik

Abstract

This report documents the program and the outcomes of Dagstuhl Seminar 14082 "Visualization and Processing of Higher Order Descriptors for Multi-Valued Data". The seminar gathered 26 senior and younger researchers from various countries in the unique atmosphere offered by Schloss Dagstuhl. The focus of the seminar was to discuss modern and emerging methods for analysis and visualization of tensor and higher order descriptors from medical imaging and engineering applications. Abstracts of the talks are collected in this report.

Published

2014

42. White matter tracing combined with electric field simulation - A patient-specific approach for deep brain stimulation.

Author

Nordin T, Zsigmond P, Pujol S, Westin CF, and Wårdell K

Subjects

Aged, Aged, 80 and over, Algorithms, Anisotropy, Diffusion Tensor Imaging, Electric Conductivity, Female, Gray Matter diagnostic imaging, Humans, Male, Thalamus diagnostic imaging, Deep Brain Stimulation methods, Essential Tremor diagnostic imaging, Essential Tremor therapy, White Matter diagnostic imaging

Abstract

Objective: Deep brain stimulation (DBS) in zona incerta (Zi) is used for symptom alleviation in essential tremor (ET). Zi is positioned along the dentato-rubro-thalamic tract (DRT). Electric field simulations with the finite element method (FEM) can be used for estimation of a volume where the stimulation affects the tissue by applying a fixed isolevel (V DBS ). This work aims to develop a workflow for combined patient-specific electric field simulation and white matter tracing of the DRT, and to investigate the influence on the V DBS from different brain tissue models, lead design and stimulation modes. The novelty of this work lies in the combination of all these components., Method: Patients with ET were implanted in Zi (lead 3389, n = 3, voltage mode; directional lead 6172, n = 1, current mode). Probabilistic reconstruction from diffusion MRI (dMRI) of the DRT (n = 8) was computed with FSL Toolbox. Brain tissue models were created for each patient (two homogenous, one heterogenous isotropic, one heterogenous anisotropic) and the respective V DBS (n = 48) calculated from the Comsol Multiphysics FEM simulations. The DRT and V DBS were visualized with 3DSlicer and superimposed on the preoperative T2 MRI, and the common volumes calculated. Dice Coefficient (DC) and level of anisotropy were used to evaluate and compare the brain models., Result: Combined patient-specific tractography and electric field simulation was designed and evaluated, and all patients showed benefit from DBS. All V DBS overlapped the reconstructed DRT. Current stimulation showed prominent difference between the tissue models, where the homogenous grey matter deviated most (67 < DC < 69). Result from heterogenous isotropic and anisotropic models were similar (DC > 0.95), however the anisotropic model consistently generated larger volumes related to a greater extension of the electric field along the DBS lead. Independent of tissue model, the steering effect of the directional lead was evident and consistent., Conclusion: A workflow for patient-specific electric field simulations in combination with reconstruction of DRT was successfully implemented. Accurate tissue classification is essential for electric field simulations, especially when using the current control stimulation. With an accurate targeting and tractography reconstruction, directional leads have the potential to tailor the electric field into the desired region., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

43. Visualization and Processing of Tensors and Higher Order Descriptors for Multi-Valued Data (Dagstuhl Seminar 11501)

Author

Bernhard Burgeth and Carl-Fredrik Westin, Burgeth, Bernhard, Westin, Carl-Fredrik, Bernhard Burgeth and Carl-Fredrik Westin, Burgeth, Bernhard, and Westin, Carl-Fredrik

Abstract

This report documents the program and the outcomes of Dagstuhl Seminar 11501 "Visualization and Processing of Tensors and Higher Order Descriptors for Multi-Valued Data", taking place December 11-16, 2011. The Seminar gathered 26 senior and younger researchers from various countries in the unique atmosphere offered by Schloss Dagstuhl. The focus of the seminar was to discuss modern and emerging methods for analysis and visualization of tensor and higher order descriptors from medical imaging and engineering applications. Abstracts of the talks are collected in this report.

Published

2012

44. Volumetric and fiber-tracing MRI methods for gray and white matter.

Author

Larvie M and Fischl B

Subjects

Brain diagnostic imaging, Humans, Image Processing, Computer-Assisted, Brain anatomy & histology, Diffusion Tensor Imaging, Gray Matter diagnostic imaging, Nerve Fibers physiology, White Matter diagnostic imaging

Abstract

Magnetic resonance imaging (MRI) is capable of generating high-resolution brain images with fine anatomic detail and unique tissue contrasts that reveal structures that are not visible to the eye. Sharply defined gray- and white-matter interfaces allow for quantitative anatomic analysis that can be accurately performed with largely automated segmentation methods. In an analogous fashion, diffusion MRI in the brain provides structural information based on contrasts derived from the diffusivity of water in brain tissue, which can highlight the orientation of neuronal axons. Also using largely automated methods, diffusion MRI can be used to generate models of white-matter tracts throughout the brain, a method known as tractography, as well as characterize the microstructural integrity of neuronal axons. Tractographic analysis has helped to define connectivity in the brain that powerfully informs understanding of brain function, and, together with other diffusion metrics, is useful in evaluation of the normal and diseased brain. The quantitative methods of brain segmentation, tractography, and diffusion MRI extend MRI into a realm beyond visual inspection and provide otherwise unachievable sensitivity and specificity in the analysis of brain structure and function., (© 2016 Elsevier B.V. All rights reserved.)

Published

2016