Objective In multiple sclerosis (MS), using simultaneous magnetic resonance-positron emission tomography (MR-PET) imaging with 11C-PBR28, we quantified expression of the 18kDa translocator protein (TSPO), a marker of activated microglia/macrophages, in cortex, cortical lesions, deep gray matter (GM), white matter (WM) lesions and normal-appearing WM (NAWM) to investigate the in vivo pathological and clinical relevance of neuroinflammation. Methods Fifteen secondary-progressive MS (SPMS) and 12 relapsing-remitting MS (RRMS) cases, and 14 matched healthy controls underwent 11C-PBR28 MR-PET. MS subjects underwent 7 Tesla T2*-weighted imaging for cortical lesions segmentation; neurological and cognitive evaluation. 11C-PBR28 binding was measured using normalized 60-90-minutes standardized uptake values and volume of distribution ratios. Results Relative to controls, MS subjects exhibited abnormally high 11C-PBR28 binding across the brain, the greatest increases being in cortex and cortical lesions, thalamus, hippocampus, and NAWM. MS WM lesions showed relatively modest TSPO increases. With the exception of cortical lesions, where TSPO expression was similar, 11C-PBR28 uptake across the brain was greater in SPMS than in RRMS. In MS, increased 11C-PBR28 binding in cortex, deep GM, and NAWM correlated with neurological disability and impaired cognitive performance; cortical thinning correlated with increased thalamic TSPO levels. Interpretation In MS, neuroinflammation is present in the cortex, cortical lesions, deep GM, and NAWM, and closely linked to poor clinical outcome and, at least partly, to neurodegeneration. Distinct inflammatory-mediated factors may underlie accumulation of cortical and WM lesions. Quantification of TSPO levels in MS could prove a sensitive tool for evaluating in vivo the inflammatory component of GM pathology, particularly in cortical lesions.
Objectives: Evaluate cross-sectionally the contribution of focal cortical lesion (CL) subtypes at ultra-high-field MRI and traditional MRI metrics of brain damage to neurologic disability and cognitive performance in a heterogeneous multiple sclerosis (MS) cohort.Methods: Thirty-four patients with early or established disease including clinically isolated syndrome, relapsing-remitting MS, and secondary progressive MS were scanned on a human 7-tesla (7T) (Siemens) scanner to acquire fast low-angle shot (FLASH) T2*-weighted images for characterization of white matter and deep gray matter lesion volume, and CL types. Patients also underwent anatomical 3T MRI for cortical thickness estimation, and neuropsychological testing within 1 week of the 7T scan. Twenty-seven patient scans were acceptable for further analysis. Neurologic disability was measured using the Expanded Disability Status Scale.Results: Type III-IV CLs had the strongest relationship to physical disability (r 5 0.670, p , 0.0001).White matter lesion volume and type I CLs are each significantly associated with 6 of 11 neuropsychological test variables. Type III-IV CLs significantly correlate with 4 of 11 neuropsychological test variables whereas type II CLs, deep gray matter lesion volume, and cortical thickness metrics are less frequently associated with cognitive performance. Cognitive dysfunction is a common but frequently overlooked clinical manifestation of multiple sclerosis (MS). 1 Frequently affected cognitive domains include executive function, processing speed, and memory. 2 Cognitive impairment in MS deleteriously affects social and vocational activities, may result in unemployment, and appears to lead to an increased vulnerability to psychiatric illness. 3 Despite the impact of cognitive dysfunction in MS, our understanding of its pathophysiology is limited. Conclusions: Leukocortical (type I) and subpial (III-IV) CLs identified on 7T FLASH-T2Conventional and quantitative MRI have identified potential biomarkers and better defined the pathophysiology of cognitive dysfunction in MS. 4 To date, global rather than regional metrics of cortical atrophy and cortical lesion (CL) volume using double inversion recovery (DIR) sequences at 3 tesla (3T) better account for the variance seen in cognitive performance in MS-supplanting conventional white matter (WM) MRI metrics. 5,6 These findings are not entirely unexpected because MS neuropathology has highlighted the cortex as a major location of demyelination. 7 Although 3T DIR is an innovative improvement over conventional imaging
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