Key Points
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MRI scanner performance and the development of multiple advanced techniques have progressed to an extent that nonconventional MRI can now be used in clinical routine
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These techniques have unravelled the diversity of microstructural tissue changes not visible with conventional MRI, which correlate with rather specific pathophysiological processes, as well as with some clinical variables
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Several other techniques—including myelin-water imaging, 23Na imaging, magnetic resonance elastography and magnetic resonance perfusion imaging—promise further insights
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The utility of these techniques in clinical trials and their applicability to clinical practice have not yet been established
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Facilitating the use of these techniques in future research and clinical practice will require standardization of protocols and harmonization of postprocessing and analysis methods
Abstract
MRI has become the most important paraclinical tool for diagnosing and monitoring patients with multiple sclerosis (MS). However, conventional MRI sequences are largely nonspecific in the pathology they reveal, and only provide a limited view of the complex morphological changes associated with MS. Nonconventional MRI techniques, such as magnetization transfer imaging (MTI), diffusion-weighted imaging (DWI) and susceptibility-weighted imaging (SWI) promise to complement existing techniques by revealing more-specific information on microstructural tissue changes. Past years have witnessed dramatic advances in the acquisition and analysis of such imaging data, and numerous studies have used these tools to probe tissue alterations associated with MS. Other MRI-based techniques—such as myelin-water imaging, 23Na imaging, magnetic resonance elastography and magnetic resonance perfusion imaging—might also shed new light on disease-associated changes. This Review summarizes the rapid technical progress in the use of MRI in patients with MS, with a focus on nonconventional structural MRI. We critically discuss the present utility of nonconventional MRI in MS, and provide an outlook on future applications, including clinical practice. This information should allow appropriate selection of advanced MRI techniques, and facilitate their use in future studies of this disease.
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Enzinger, C., Barkhof, F., Ciccarelli, O. et al. Nonconventional MRI and microstructural cerebral changes in multiple sclerosis. Nat Rev Neurol 11, 676–686 (2015). https://doi.org/10.1038/nrneurol.2015.194
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