Magnetic Resonance Imaging (MRI) has revolutionized our ability to non-invasively study the brain's structural and functional properties. However, detecting myelin, a crucial component of white matter, remains challenging due to its indirect visibility on conventional MRI scans. Myelin plays a vital role in neural signal transmission and is associated with various neurological conditions. Understanding myelin distribution and content is crucial for insights into brain development, aging, and neurological disorders. Although specialized MRI sequences can estimate myelin content, these are time-consuming. Also, many patients sent to specialized neurological centers have an MRI of the brain already scanned. In this study, we focused on techniques utilizing standard MRI T1-weighted (T1w) and T2 weighted (T2w) sequences commonly used in brain imaging protocols. We evaluated the applicability of the T1w/T2w ratio in assessing myelin content by comparing it to quantitative T1 mapping (qT1). Our study included 1 healthy adult control and 7 neurologic patients (comprising both pediatric and adult populations) with epilepsy originating from focal epileptogenic lesions visible on MRI structural scans. Following image acquisition on a 3T Siemens Vida scanner, datasets were co registered, and segmented into anatomical regions using the Fastsurfer toolbox, and T1w/T2w ratio maps were calculated in Matlab software. We further assessed interhemispheric differences in volumes of individual structures, their signal intensity, and the correlation of the T1w/T2w ratio to qT1. Our data demonstrate that in situations where a dedicated myelin-sensing sequence such as qT1 is not available, the T1w/T2w ratio provides significantly better information than T1w alone. By providing indirect information about myelin content, this technique offers a valuable tool for understanding the neurobiology of myelin-related conditions using basic brain scans.

Department of Neurology 2nd Faculty of Medicine Charles University and University Hospital Motol Prague Czech Republic

Department of Pathophysiology 2nd Faculty of Medicine Charles University Czech Republic

Department of Pathophysiology 2nd Faculty of Medicine Charles University Praha 5 Czech Republic

Department of Pediatric Neurology 2nd Faculty of Medicine Charles University and University Hospital Motol Prague Czech Republic

Department of Radiology 2nd Faculty of Medicine Charles University and University Hospital Motol Prague Czech Republic

Faculty of Electrical Engineering Czech Technical University Prague Czech Republic

Laboratory of Developmental Epileptology Institute of Physiology of the Czech Academy of Sciences Prague Czech Republic

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