Development and application of quantitative MRI methods for assessing white matter integrity in the mouse brain

Thiessen, Jonathan

28 September 2012

Healthy white matter in the brain and spinal cord is composed primarily of myelinated axons and glial cells. Myelinated axons transfer information between the peripheral nervous system and the central nervous system (CNS) as well as between centres within the CNS. Demyelination, a hallmark of neurodegenerative autoimmune diseases such as multiple sclerosis (MS), can cause nerve damage and degrade signal propagation. Magnetic resonance imaging (MRI) methods thought to assess myelin integrity and the structural integrity of axons are improving both the diagnosis and understanding of white matter diseases such as MS. Current methods, however, are sensitive to many different pathologies, making the interpretation of individual MRI results difficult. For this dissertation, several quantitative MRI methods were developed and compared, including single component T1 and T2 relaxometry, multicomponent T2 relaxometry, diffusion tensor imaging (DTI), and quantitative magnetization transfer imaging (qMTI). These methods were tested on agarose gels, fixed rat spinal cords, healthy control mice, and the cuprizone mouse model of demyelination. Quantitative MRI measurements were correlated to ultrastructural measurements of white matter to determine the influence myelin content and axonal structure have on different MRI methods. Cellular distributions measured in electron micrographs of the corpus callosum correlated strongly to several different quantitative MRI metrics. The largest Spearman correlation coefficient varied depending on cellular type: longitudinal relaxation rates (RA/T1) vs. the myelinated axon fraction ( r = 0.90/-0.90), the qMTI-derived bound pool fraction (f) vs. the myelin sheath fraction ( r = 0.93), and the DTI-derived axial diffusivity vs. the non-myelinated cell fraction (r = 0.92). Using Pearson’s correlation coefficient, f was strongly correlated to the myelin sheath fraction (r = 0.98) with a linear equation predicting myelin content (5.37f −0.25). Of the calculated MRI metrics, f was the strongest indicator of myelin content while longitudinal relaxation rates and diffusivity measurements were the strongest indicators of changes in tissue structure. Multiparametric MRI measurements of relaxation, diffusion, and magnetization transfer give a more complete picture of white matter integrity.

magnetic resonance imaging

diffusion tensor imaging

magnetization transfer imaging

relaxometry

demyelination

cuprizone

corpus callosum

myelin

electron microscopy

multiple sclerosis

white matter

image processing

Development and application of quantitative MRI methods for assessing white matter integrity in the mouse brain

Thiessen, Jonathan

28 September 2012

Healthy white matter in the brain and spinal cord is composed primarily of myelinated axons and glial cells. Myelinated axons transfer information between the peripheral nervous system and the central nervous system (CNS) as well as between centres within the CNS. Demyelination, a hallmark of neurodegenerative autoimmune diseases such as multiple sclerosis (MS), can cause nerve damage and degrade signal propagation. Magnetic resonance imaging (MRI) methods thought to assess myelin integrity and the structural integrity of axons are improving both the diagnosis and understanding of white matter diseases such as MS. Current methods, however, are sensitive to many different pathologies, making the interpretation of individual MRI results difficult. For this dissertation, several quantitative MRI methods were developed and compared, including single component T1 and T2 relaxometry, multicomponent T2 relaxometry, diffusion tensor imaging (DTI), and quantitative magnetization transfer imaging (qMTI). These methods were tested on agarose gels, fixed rat spinal cords, healthy control mice, and the cuprizone mouse model of demyelination. Quantitative MRI measurements were correlated to ultrastructural measurements of white matter to determine the influence myelin content and axonal structure have on different MRI methods. Cellular distributions measured in electron micrographs of the corpus callosum correlated strongly to several different quantitative MRI metrics. The largest Spearman correlation coefficient varied depending on cellular type: longitudinal relaxation rates (RA/T1) vs. the myelinated axon fraction ( r = 0.90/-0.90), the qMTI-derived bound pool fraction (f) vs. the myelin sheath fraction ( r = 0.93), and the DTI-derived axial diffusivity vs. the non-myelinated cell fraction (r = 0.92). Using Pearson’s correlation coefficient, f was strongly correlated to the myelin sheath fraction (r = 0.98) with a linear equation predicting myelin content (5.37f −0.25). Of the calculated MRI metrics, f was the strongest indicator of myelin content while longitudinal relaxation rates and diffusivity measurements were the strongest indicators of changes in tissue structure. Multiparametric MRI measurements of relaxation, diffusion, and magnetization transfer give a more complete picture of white matter integrity.

magnetic resonance imaging

diffusion tensor imaging

magnetization transfer imaging

relaxometry

demyelination

cuprizone

corpus callosum

myelin

electron microscopy

multiple sclerosis

white matter

image processing

Estudo da correlação entre a razão de transferência de magnetização e a volumetria em pacientes com lesão axonal traumática / Correlation between the magnetization transfer ratio and brain volume in patients with traumatic axonal injury

Macruz, Fabíola Bezerra de Carvalho

08 February 2019

Introdução: A lesão axonal traumática (LAT) ou lesão axonal difusa (LAD) esta presente em grande parte dos traumatismos crânio-encefálicos (TCE), sendo importante causa de mortalidade e morbidade das suas vítimas. A LAT dispara uma sequência de mudanças neurodegenerativas encefálicas que são, paradoxalmente, acompanhadas por recuperação cognitiva. Objetivo: Avaliar quantitativamente a LAT, através da razão de transferência de magnetização (RTM) e de medidas volumétricas para caracterizar a evolução temporoespacial das mudanças macroscópicas e microscópicas e investigar possível correlação entre elas, auxiliando no entendimento da sua fisiopatologia. Este estudo ainda investigou correlação entre atrofia e dano axonal/mielínico e a evolução funcional. Métodos: Imagens 3D-T1, 3DGE (PRESTO) e de transferência de magnetização (ITM) foram obtidas de 26 pacientes vítimas de TCE moderado e grave e de 26 controles, de idade e sexo semelhantes. Os pacientes foram submetidos a RM com 2 (fase aguda tardia/subaguda), 6 (crônica precoce) e 12 (crônica tardia) meses do TCE. A RM foi realizada nos controles em apenas uma única ocasião. Através de métodos automatizados, calculou-se o volume da substancia cinzenta (SC), da substancia branca (SB) e do encéfalo total (ET), ajustando-os pelo volume intracraniano. A partir de histogramas da RTM obtidos das mesmas regiões, calculou-se a média e os percentis 25, 50 e 75% da RTM. As imagens PRESTO foram usadas na exclusão dos focos hemorrágicos da análise da RTM, nos pacientes. A evolução funcional foi medida pela escala prognostica de Glasgow (EPG), realizada um ano após o TCE. Resultados: A RTM media e o volume foram significativamente diferentes nos pacientes e nos controles. Os pacientes apresentaram RTM media maior (p < 0,05) e volume menor na SC e ET, desde o primeiro exame (fase aguda tardia/subaguda precoce). Na SB, valores menores tanto da RTM media (p=0,02) quanto do volume (p=0,009) foram observados nos pacientes apenas no terceiro exame (fase crônica tardia). Redução progressiva da RTM media dos pacientes foi observada em todos os compartimentos, estimada em 1,14% na SC, 1,38% na SB e 1,40% no ET durante todo o estudo. Houve também redução volumétrica gradual da SB e do ET, com taxa de atrofia total de 3,20% e 1,50%, respectivamente. Não houve relação entre redução da RTM media e atrofia. Nenhum dos parâmetros mostrou valor prognostico nas fases subaguda ou crônica precoce. Conclusões: A LAT resulta numa rarefação axonal/mielínica e redução volumétrica progressiva do tecido encefálico, que se perpetua por até um ano do trauma. As mudanças são mais expressivas e prolongada na SB. A redução do volume e da RTM media se mostraram independentes na LAT. Isso sugere que os dois parâmetros reflitam aspectos complementares da fisiopatologia da LAT, em níveis micro e macroestrutural / Introduction: Traumatic axonal injury (TAI) or diffuse axonal injury (DAI) is a frequent component of traumatic brain injury (TBI) and a major cause of mortality and morbidity in this population. It triggers a sequence of degenerative changes in the brain, that are paradoxically accompanied by cognitive recovery. Purposes: The present study used magnetization transfer ratio (MTR) and volumetric data to appreciate the spatiotemporal evolution of macroscopic and microscopic changes and investigate possible correlation between them, enhancing the knowledge about its pathophysiology. It also investigated correlation between atrophy and axonal/myelin damage and functional outcome. Methods: Volumetric T1-weighted, 3DGE (PRESTO) and magnetization transfer images (MTI) were obtained from 26 patients who experienced moderate to severe TBI and 26 age- and sex-matched controls. Patients were scanned at 2 (late acute/subacute stage), 6 (early chronic) and 12 months (late chronic) postinjury and controls, only once. Whole brain (WB), gray matter (GM) and white matter (WM) volumes were measured using automated technique and adjusted for intracranial volume. Histogram analysis was performed in the same regions, with calculation of the mean MTR and its 25, 50 and 75% percentiles. The PRESTO images were used to exclude the small lesions from the MTR analysis in the patients. Functional outcome was assessed 12 months after injury using the Glasgow Outcome Scale (GOS). Results: Mean MTR and volume were significantly different between patients and controls. Patients presented higher mean MTR values (p < 0,05) and smaller volume (p < 0,05) in the GM and WB, as of the first exam (late acute/subacute stage). In the WM, reduction of both, the mean MTR (p=.02) and volume (p=.009), was observed only in their third exam (late chronic stage). Progressive decrease of patients\' mean MTR was observed in all compartments, with rates of 1.14% for the GM, 1.38% for the WM and 1.40% for the WB across the study. Continuing reduction of the WM and WB volume was also observed, with total atrophy rate of 3.20% and 1.50%, respectively. No correlation between mean MT and the volumetric changes was found. None of the parameters showed prognostic value during the subacute and early chronic stages. Conclusions: TAI results in a progressive axonal/myelinic rarefaction and volumetric brain reduction that continues until a year postinjury. The changes are greater and lasts longer in the WM. The reduction in the volume and mean MTR were independent between them in TAI. This suggests that the two parameters reflect complementary aspects of the TAI pathologic lesion at macro and microstructural levels

Atrofia

Atrophy

Axonal-myelinic damage

Brain injuries traumatic

Craniocerebral trauma

Dano axonal-mielínico

Diagnostic imaging

Diagnóstico por imagem

Diffuse axonal injury

Lesão axonal difusa

Lesões encefálicas traumáticas

Magnetization transfer imaging

Traumatismos craniocerebrais

Toward the characterization of micro- and macro- traumatisms of the human cervical spinal cord in rugby : a multimodal approach combining magnetic resonance imaging and biomechanical finite element modelling / Vers la caractérisation des micros et macro-traumatismes de la moelle épinière cervicale dans la pratique du rugby : une approche multimodale combinant imagerie par résonnance magnétique et modélisation biomécanique par éléments finis

Rasoanandrianina, Rivo

08 January 2019

Dans la pratique du rugby à XV, l’intégrité de la moelle épinière (ME) est menacée par les rares macro-traumatismes du rachis cervical, et par les chargements répétitifs entrainant l’apparition de pathologies dégénératives. Comment quantifier ces altérations, quels sont les mécanismes qui les président ?Pour aborder ces questions, la faisabilité et l’intérêt d’un protocole IRM multiparamétrique en contexte dégénératif ont tout d’abord été investigués. Puis, une récente technique de relaxométrie T1 3D et une acquisition ihMT multi-coupes à multiples orientations permettant d’évaluer le contenu macromoléculaire des tissus, en particulier la myéline, ont été développées pour évaluer le caractère diffus des altérations. Préliminairement appliqué sur quelques joueurs, ce protocole a ainsi démontré la faisabilité d’une exploration approfondie par IRM multiparamétrique de la ME cervicale dans le rugby.En complément de cela, une étude préliminaire utilisant un modèle éléments finis (MEF) détaillé a été menée pour évaluer la réponse mécanique des sous-régions de la ME soumises à des chargements mécaniques primaires. Par la suite, une étude préliminaire des risques neurologiques liés à un canal vertébral étroit (observé chez certains joueurs) a été conduite en modifiant la géométrie du MEF. A l’interface entre l’IRM et la biomécanique, ces travaux préliminaires ont posé les premiers jalons pour une caractérisation fine et robuste des altérations tissulaires au niveau médullaire dans le rugby. A terme, cette approche permettrait de proposer de nouveaux éléments pour une éventuelle amélioration du bilan d’aptitude des joueurs et de proposer des programmes préventifs améliorés. / In Rugby Union practice, the cervical spinal cord (CSC) could be involved in rare cervical spine (CS) traumatic injuries and also be threatened by the neck exposure to repetitive impacts assumed to induce early degenerative tissue alterations. How to quantify these impairments? What are the underlying pathophysiological mechanisms? To answer these questions, efforts were first directed towards the investigative potential of an advanced multiparametric Magnetic Resonance Imaging (MRI) protocol in degenerative contexts. Then, a new MRI protocol covering the whole CSC, including a recent 3D T1 relaxometry technique and a multi-slice multi-angle ihMT acquisition evaluating tissue myelin-content, was optimized. Preliminarily-applied to few players, this new optimized protocol showed the feasibility of a fine and diffuse CSC characterization in rugby. In parallel and as a complement, preliminary finite element modelling (FEM) analyses were also conducted to evaluate the mechanical responses of CSC sub-regions under primary loading mechanisms. Then, the same loading mechanisms were applied to a geometrically-modified FEM reproducing a narrow vertebral canal, reported to occur in some players therefore allowing to evaluate the effect of rugby-related CS degenerative changes on the CSC mechanical response under traumatic loadings. These preliminary, interdisciplinary and complementary works lay the ground for a fine structural and mechanical characterization of CSC tissues in rugby players, which would eventually allow to propose improved aptitude-to-play evaluation criteria as well as improved preventive programs.

Moelle épinière

Rugby

Micro-Traumatismes

Macro-Traumatismes

Imagerie par Résonance Magnétique

Modélisation par éléments finis

Simulation numérique

Imagerie du tenseur de diffusion

Imagerie du transfert d'aimantation

Relaxométrie

Spinal cord

Rugby

Micro-Traumatisms

Macro-Traumatisms

Magnetic Resonance Imaging

Finite element modelling

Numerical simulation

Diffusion Tensor Imaging

Magnetization Transfer imaging

Relaxometry

612

Quantitative Myelinbildgebung bei Erkrankungen der weißen Hirnsubstanz im Kindes- und Jugendalter / Quantitative myelin imaging of childhood white matter disorders

Preuße, Matthias

23 February 2021

No description available.

610

Magnetisierungstransfer-Bildgebung

Diffusionstensor-Bildgebung

Magnetisierungstransfer-Sättigung

Adrenoleukodystrophie

Pelizaeus-Merzbacher-Syndrom

zerebrale Folatdefizienz

magnetization transfer imaging

diffusion tensor imaging

magnetization transfer saturation

adrenoleukodystrophy

Pelizaeus–Merzbacher disease

cerebral folate deficiency

Pädiatrie, Neonatologie (PPN619876107)