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[11C]K-2 image with positron emission tomography represents cell surface AMPA receptors

Tetsu Arisawa, Tomoyuki Miyazaki, Wataru Ota, Akane Sano, Kumiko Suyama, Yuuki Takada, Takuya Takahashi

2021Neuroscience Research22 citationsDOIOpen Access PDF

Abstract

The glutamate α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid receptors (AMPARs) is an important molecule in neurotransmission. We have recently developed the first positron emission tomography (PET) tracer [11C]K-2 to visualize and quantify AMPARs in the living human brain. After injection, [11C]K-2 is hydrolyzed at the terminal amide (and is thus metabolized to a major metabolite, [11C]K-2OH) within 10 min, representing the PET image in rodents and humans. Here, we found that K-2OH did not penetrate the cell membrane but slowly passed through the blood brain barrier (BBB) with paracellular transport. Furthermore, major efflux transporters in the BBB did not carry K-2OH. Logan graphical analysis exhibited reversible binding kinetics of this radiotracer in healthy individuals; these results demonstrated that the PET image of this tracer represents cell surface AMPARs with passive penetration of [11C]K-2OH through the BBB, resulting in reversible binding kinetics. Thus, PET images with this tracer depict the physiologically crucial fraction of AMPARs.

Topics & Concepts

Positron emission tomographyChemistryAMPA receptorParacellular transportBiophysicsBlood–brain barrierReceptorGlutamate receptorMetaboliteBiochemistryNeuroscienceMembranePermeability (electromagnetism)BiologyCentral nervous systemNeuroscience and Neuropharmacology ResearchDrug Transport and Resistance MechanismsAmino Acid Enzymes and Metabolism
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