News Release

Translational PET tracer visualizes brain cholesterol metabolism

Peer-Reviewed Publication

Society of Nuclear Medicine and Molecular Imaging

Clinical translation of 18F-Cholestify in healthy volunteers.

image: Clinical translation of 18F-Cholestify in healthy volunteers. Representative PET and non-displaceable binding potential in humans. Correlations of regional PET signal (SUV) with non-displaceable binding potential values and Western blot analysis of CYP46A1 from post-mortem brain specimens. view more 

Credit: Image created by Steven Liang, Emory University .

Chicago, Illinois (Embargoed until 12:55 p.m. CDT, Sunday, June 25, 2023)—A new PET radiotracer that visualizes the enzyme primarily responsible for metabolic cholesterol degradation in the brain has been successfully validated, according to research presented at the 2023 Society of Nuclear Medicine and Molecular Imaging Annual Meeting. Known as 18F-Cholestify, the radiotracer holds the potential to substantially improve clinical neuroimaging, laying the foundation for new image-guided trials to study neurodegenerative diseases and neurological disorders. 

Brain cholesterol metabolism is impaired in many neurodegenerative diseases and neurological disorders, including Alzheimer’s disease. However, there are no validated methods currently available to visualize metabolic cholesterol clearance in the brain. 

“Given the scarcity of tools to image brain cholesterol metabolism, a PET radioligand that is suitable for quantitative mapping of CYP46A—the enzyme that eliminates excessive brain cholesterol—could broadly affect disease diagnosis and treatment options,” stated Steven Liang, PhD, associate professor in the Department of Radiology and Imaging Sciences and head of the PET Imaging Center at Emory University in Atlanta, Georgia. “In response to this need, we developed a CYP46A1-targeted PET radioligand with high CYP4A1 binding affinity and tested in across different species to evaluate tracer performance characteristics.” 

18F-Cholestify was created by radiolabeling the molecule CHL2205 with fluorine-18. To investigate its effectiveness, the affinities of CHL2205 in rats, non-human primates, and humans were determined by radioligand saturation/competitive binding assays. Autoradiographies were performed on rodent brain tissue, and PET imaging studies were conducted in rats, non-human primates and healthy volunteers.  

Preclinical evaluation of 18F-Cholestify in rats showed remarkable selectivity for CYP46A-rich brain regions such as the striatum, cortex, thalamus, and hippocampus. Regional selectivity for CYP46A1-rich brain areas was confirmed in non-human primate PET studies and in a first-in-human study. Kinetic modeling revealed excellent correlation of the PET signal with non-displaceable binding potentials as well as with Western-blot results in post-mortem specimens in non-human primates. 

“In this study we successfully performed cross-species validation of our target structure, CHL2205, using a variety of radioligand binding assays. Remarkably, the PET signal intensity observed in vivo in mice, non-human primates and humans exhibited a direct correlation with protein expression levels detected in postmortem brain specimens across all species,” stated Liang. “The compelling findings warrant the imminent integration of 18F-cholestify PET imaging into clinical studies for neurodegenerative diseases and neurological disorders.”

Looking to the future, Liang noted that there is accumulating evidence that brain cholesterol is implicated in early Alzheimer’s disease pathology, making it a target of interest. “While amyloid-targeted antibodies hold promise for modifying the disease process, their clinical efficacy and long-term effects are still being evaluated. As such, it is of paramount importance to foster research into exploring the potential of combination therapies, as well as investigating other approaches targeting different aspects of Alzheimer's disease pathology,” he said. 

Abstract 799. “Translational Radioligand Development to Visualize Brain Cholesterol Metabolism.” Steven H. Liang, Ahmed Haider, Chunyu Zhao, Jian Rong, Jiahui Chen, Yinlong Li, Lee Collier, David Schuster, and Allan Levey, Emory University, Atlanta, Georgia. 

Link to Session  

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All 2023 SNMMI Annual Meeting abstracts can be found online.  

About the Society of Nuclear Medicine and Molecular Imaging 
The Society of Nuclear Medicine and Molecular Imaging (SNMMI) is an international scientific and medical organization dedicated to advancing nuclear medicine and molecular imaging—vital elements of precision medicine that allow diagnosis and treatment to be tailored to individual patients in order to achieve the best possible outcomes. 

SNMMI’s members set the standard for molecular imaging and nuclear medicine practice by creating guidelines, sharing information through journals and meetings and leading advocacy on key issues that affect molecular imaging and therapy research and practice. For more information, visit www.snmmi.org.  


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