Shir Filo | Increasing the molecular specificity of quantitative MRI
Guest Lecture
- Date: May 29, 2024
- Time: 02:00 PM - 03:00 PM (Local Time Germany)
- Speaker: Shir Filo
- Edmond & Lily Safra Center for Brain Sciences, the Hebrew University of Jerusalem, Israel
- Room: Charlotte Buehler Room (C402)
- Host: Department of Neurophysics
- Contact: amuehlberg@cbs.mpg.de
Comprehensive description of brain tissue's microstructure is crucial for studying the normal and diseased brain. In the talk I will present an in-vivo biophysical framework for increasing the specificity of quantitative MRI to distinct microstructural features of brain tissue, such as the lipid composition and the iron homeostasis. This non-invasive approach identifies lipidomic-related changes in the aging human brain, and allows to test different aging theories. This approach also reveals the disrupted iron homeostasis in brain tumors, and provides iron-related information inaccessible by conventional MRI approaches. Finally, I will propose a new MRI protocol, for implementing this qMRI approach at the sub-voxel level. By monitoring microstructural processes in living brains, we hope to gain a quantitative and specific description of brain tissue that until now was possible only post-mortem, and may further advance human brain research.
Comprehensive description of brain tissue's microstructure is crucial for studying the normal and diseased brain. In the talk I will present an in-vivo biophysical framework for increasing the specificity of quantitative MRI to distinct microstructural features of brain tissue, such as the lipid composition and the iron homeostasis. This non-invasive approach identifies lipidomic-related changes in the aging human brain, and allows to test different aging theories. This approach also reveals the disrupted iron homeostasis in brain tumors, and provides iron-related information inaccessible by conventional MRI approaches. Finally, I will propose a new MRI protocol, for implementing this qMRI approach at the sub-voxel level. By monitoring microstructural processes in living brains, we hope to gain a quantitative and specific description of brain tissue that until now was possible only post-mortem, and may further advance human brain research.