771 research outputs found
Myelin imaging and characterization by magnetic resonance imaging
280 p.Los axones neuronales están recubiertos de una membrana lipídica llamada mielina, que protege a los axones y posibilita una transmisión rápida y eficiente del impulso eléctrico. En ciertas patologías como la lesión cerebral traumática, la isquemia o principalmente, en la esclerosis múltiple, la pérdida de mielina o desmielinización da lugar a la muerte neuronal y por consiguiente a la pérdida de capacidades cognitivas. Este estado puede ser revertido por medio de la remielinización, en la que los oligodendrocitos mielinizantes del sistema nervioso central regeneran la vaina de mielina, evitando la degeneración de las neuronas. En los últimos años se ha realizado un esfuerzo considerable en el desarrollo de terapias remielinizantes. Para ello, es imprescindible el desarrollo de técnicas para la evaluación no-invasiva de estas terapias y una caracterización profunda de los procesos de desmielinización y remielinización. En este contexto, la imagen por resonancia magnética (IRM) juega un papel fundamental por su carácter no-invasivo, alta resolución y versatilidad.Los principales objetivos de esta tesis han sido el desarrollo de protocolos de IRM para la cuantificación de mielina y la caracterización de los procesos de remielinización y desmielinización a través de resonancia magnética funcional en reposo. Para ello se ha utilizado como base el modelo murinocuprizona, en la que la administración del tóxico da lugar a la desmielinización en el cerebro, seguido por la remielinización. Los datos y conclusiones obtenidas se han contrastado en otros modelos de ratón, como en modelos de Alzheimer o en ratones sanos envejecidos.A grandes rasgos, hemos podido concluir que la imagen ponderada en peso T2 es la más específica y sensible para la cuantificación de mielina en el modelo cuprizona. Por ello, en este trabajo se propone la utilización de la imagen ponderada en peso T2 para la evaluación de terapias remielinizantes en el modelo cuprizona. Sin embargo, el interés de realizar imagen multiparamétríca ha quedado al descubierto al realizar imagen de modelos de ratón de Alzheimer, pudiendo detectar patología no relacionada con pérdida de mielina en zonas de materia blanca.Así mismo, hemos podido comprobar como la desmielinización conlleva la pérdida de la conectividad y función cerebral y la remielinización posibilita la recuperación por medio de la resonancia magnética funcional en reposo. Además, el potencial agente remielinizante clemastina, ha demostrado su capacidad de promover la remielinización a nivel anatómico y funcional tras 2 semanas de tratamiento. Finalmente, se ha realizado un estudio para determinar el efecto del envejecimiento en la conectividad del cerebro. Hemos podido observar que en ratones sanos, se ha observado un incremento de la conectividad cerebral hasta el mes 8, seguido de un descenso hasta el mes 13, probablemente debido a la neurodegeneración.En este trabajo hemos contribuido al desarrollo de terapias remielinizantes, por un lado, desarrollando protocolos de imagen para la cuantificación de mielina en modelos animales y por otro lado, caracterizando la desmielinización y remielinización a nivel funcional y anatómico
Utility of Diffusion and Magnetization Transfer MRI in Cervical Spondylotic Myelopathy: A Pilot Study
Diffusion tensor imaging (DTI) and magnetization transfer (MT) magnetic resonance imaging (MRI) can help detect spinal cord pathology, and tract-specific analysis of their parameters, such as fractional anisotropy (FA), mean diffusivity, axial diffusivity (AD), radial diffusivity (RD) and MT ratio (MTR), can give microstructural information. We performed the tract-based acquisition of MR parameters of three major motor tracts: the lateral corticospinal (CS), rubrospinal (RuS) tract, and lateral reticulospinal (RS) tract as well as two major sensory tracts, i.e., the fasciculus cuneatus (FC) and spinal lemniscus, to detect pathologic change and find correlations with clinical items. MR parameters were extracted for each tract at three levels: the most compressed lesion level and above and below the lesion. We compared the MR parameters of eight cervical spondylotic myelopathy patients and 12 normal controls and analyzed the correlation between clinical evaluation items and MR parameters in patients. RuS and lateral RS showed worse DTI parameters at the lesion level in patients compared to the controls. Worse DTI parameters in those tracts were correlated with weaker power grasp at the lesion level. FC and lateral CS showed a correlation between higher RD and lower FA and MTR with a weaker lateral pinch below the lesion level.ope
Traumatic and nontraumatic spinal cord injury: pathological insights from neuroimaging
Pathophysiological changes in the spinal cord white and grey matter resulting from injury can be observed with MRI techniques. These techniques provide sensitive markers of macrostructural and microstructural tissue integrity, which correlate with histological findings. Spinal cord MRI findings in traumatic spinal cord injury (tSCI) and nontraumatic spinal cord injury — the most common form of which is degenerative cervical myelopathy (DCM) — have provided important insights into the pathophysiological processes taking place not just at the focal injury site but also rostral and caudal to the spinal injury. Although tSCI and DCM have different aetiologies, they show similar degrees of spinal cord pathology remote from the injury site, suggesting the involvement of similar secondary degenerative mechanisms. Advanced quantitative MRI protocols that are sensitive to spinal cord pathology have the potential to improve diagnosis and, more importantly, predict outcomes in patients with tSCI or nontraumatic spinal cord injury. This Review describes the insights into tSCI and DCM that have been revealed by neuroimaging and outlines current activities and future directions for the field
Influence of corpus callosum damage on cognition and physical disability in multiple sclerosis: a multimodal study.
Background Corpus callosum (CC) is a common target for multiple sclerosis (MS) pathology. We investigated the influence of CC damage on physical disability and cognitive dysfunction using a multimodal approach. Methods Twenty-one relapsing-remitting MS patients and 13 healthy controls underwent structural MRI and diffusion tensor of the CC (fractional anisotropy; mean diffusivity, MD; radial diffusivity, RD; axial diffusivity). Interhemisferic transfer of motor inhibition was assessed by recording the ipsilateral silent period (iSP) to transcranial magnetic stimulation. We evaluated cognitive function using the Brief Repeatable Battery and physical disability using the Expanded Disability Status Scale (EDSS) and the MS Functional Composite (MSFC) z-score. Results The iSP latency correlated with physical disability scores (r ranged from 0.596 to 0.657, P values from 0.004 to 0.001), and with results of visual memory (r = −0.645, P = 0.002), processing speed (r = −0.51, P = 0.018) and executive cognitive domain tests (r = −0.452, P = 0.039). The area of the rostrum correlated with the EDSS (r = −0.442, P = 0.045). MD and RD correlated with cognitive performance, mainly with results of visual and verbal memory tests (r ranged from −0.446 to −0.546, P values from 0.048 to 0.011). The iSP latency correlated with CC area (r = −0.345, P = 0.049), volume (r = −0.401, P = 0.002), MD (r = 0.404, P = 0.002) and RD (r = 0.415, P = 0.016). Conclusions We found evidence for structural and microstructural CC abnormalities associated with impairment of motor callosal inhibitory conduction in MS. CC damage may contribute to cognitive dysfunction and in less extent to physical disability likely through a disconnection mechanism
Histological correlation of diffusional kurtosis and white matter modeling metrics in cuprizone-induced corpus callosum demyelination
The cuprizone mouse model is well established for studying the processes of both demyelination and remyelination in the corpus callosum, and it has been utilized together with diffusion tensor imaging (DTI) to investigate myelin and axonal pathology. Although some underlying morphological mechanisms contributing to the changes in diffusion tensor (DT) metrics have been identified, the understanding of specific associations between histology and diffusion measures remains limited. Diffusional kurtosis imaging (DKI) is an extension of DTI that provides metrics of diffusional non-Gaussianity, for which an associated white matter modeling (WMM) method has been developed. The main goal of the present study was to quantitatively assess the relationships between diffusion measures and histological measures in the mouse model of cuprizone-induced corpus callosum demyelination. The diffusional kurtosis (DK) and WMM metrics were found to provide additional information that enhances the sensitivity to detect the morphological heterogeneity in the chronic phase of the disease process in the rostral segment of the corpus callosum. Specifically, in the rostral segment, axonal water fraction (d = 2.6; p < 0.0001), radial kurtosis (d = 2.0; p = 0.001) and mean kurtosis (d = 1.5; p = 0.005) showed the most sensitivity between groups with respect to yielding statistically significant p values and high Cohen's d values. These results demonstrate the ability of DK and WMM metrics to detect white mater changes and inflammatory processes associated with cuprizone-induced demyelination. They also validate, in part, the application of these new WMM metrics for studying neurological diseases, as well as helping to elucidate their biophysical meaning.postprin
Characterization of an Orthotopic Rat Model of Glioblastoma Using Multiparametric Magnetic Resonance Imaging and Bioluminescence Imaging
Glioblastoma multiforme (GBM) is a lethal and incurable disease. The C6 rat model of GBM shares several similarities to human GBM and longitudinal non-invasive imaging may allow tumour features to be studied. In this thesis, a multimodality imaging framework, consisting of bioluminescence imaging (BLI) and multiparametric magnetic resonance imaging (mpMRI), was applied to the C6 rat model to characterize the growth of orthotopic tumours. BLI signal, a measure of cell viability, tended to increase and then decrease in the majority of animals, whereas tumour volume (from MRI) continually increased. Cellular viability and tumour volume did not correlate across all days, highlighting the value of using complimentary imaging modalities. Apparent diffusion coefficient maps and immunohistochemistry suggests decreases in BLI signal are in part due to decreased tumour cellularity (i.e. necrosis). This is the first use of BLI and mpMRI to characterize this model, and highlights the inter-subject variability in tumour growth
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