Multiple sclerosis (MS) is the most common chronic inflammatory disease of the central nervous system1, whose demyelination is the pathological hallmark. MS is characterized by neuroinflammation, demyelination, axonal damage, and neurodegeneration2. The demyelination state in brain and the clinical course are difficult to predict in the early stage of disease. Recently, several neuroimaging and fluid biomarkers had been explored in MS. Using brain amyloid positron emission tomography (PET) in active MS had showed that both the damage sites and normal appearance white matter had a lower intensity than non-active MS. The result suggests a predictive role that the intensity from amyloid PET could reflect the disease activity and link to early myelin damage. The levels of tau protein in cerebrospinal fluid (CSF) had also been showed a negative correlation with brain atrophy, which is a prognostic marker for MS. In fluid biomarkers, both neurofilament light chain (NfL) and glial fibrillary acidic protein (GFAP) had been used in MS and reported correlations with disease severity, the extent of neuroinflammation and progression. In current study, investigator will enroll 38 participants with MS and evaluate their clinical severity; measure the WM lesion and disease activity by magnetic resonance imaging (MRI); myelination state and amyloid deposition by amyloid PET scan; tau deposition by state of-art tau PET scan. Investigator also measure the serum levels of NfL and GFAP as the index of axonal injury and disease activity. The relationship between disease severity, brain myelination, tau deposition and serum levels of NfL will be discuss.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
DIAGNOSTIC
Masking
NONE
Enrollment
38
18F-PM-PBB3 brain PET studies will be conducted for 38 subjects. Dynamic PET/MRI studies will be collected by PET/MRI scanner for 100 minutes (4×15 s, 8×30 s, 960 s, 2×180 s, 8300 s, 3×600 s). Volumes of interest (VOIs) will be delineated from corresponding MR images by manual including bilateral frontal, parietal, mesial temporal, lateral temporal, hippocampal, occipital, anterior cingulate, posterior cingulate, cerebellum areas, and genu region of white matter. The DVRs will be computed from Logan graphic analysis by using cerebellum as reference input. SUVR of every cortical VOI to the gray matter of cerebellum will be calculated from nine 10-min dynamic image sets.
Correlation between hyperintensity lesions in FLAIR MRI and demyelination in amyloid PET image
Investigator would be able to find the topographical correlation between hyperintensity lesions in FLAIR MRI and hypointensity lesions in amyloid PET, measurement by overlapping volume (ml) and overlapping ratio (%)
Time frame: 3 years
Correlation between clinical parameters (EDSS) and hyperintensity lesions in FLAIR MRI and hyperintensity region of tau PET image light chain and GFAP levels.
Investigator would be able to find the EDSS correlation between whole brain hyperintensity lesions in FLAIR MRI (ml) and hyperintensity regions of tau PETwe will take this advantage to perform the study and explore the relationship between serum neruofilament light chain and GFAP levels.
Time frame: 3 years
Correlation between clinical parameters (EDSS) and serum NfL levels
Investigator would be able to find the EDSS correlation between EDSS and serum NfL levels
Time frame: 3 years
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