Your search keyword '"Henderson, Bradford D."' showing total 2 results

1. Strategies for the Production of [ 11 C]LY2795050 for Clinical Use.

Author

Kaur T, Shao X, Horikawa M, Sharninghausen LS, Preshlock S, Brooks AF, Henderson BD, Koeppe RA, DaSilva AF, Sanford MS, and Scott PJH

Abstract

This report describes a comparison of four different routes for the clinical-scale radiosynthesis of the κ-opioid receptor antagonist [ 11 C]LY2795050. Palladium-mediated radiocyanation and radiocarbonylation of an aryl iodide precursor as well as copper-mediated radiocyanation of an aryl iodide and an aryl boronate ester have been investigated. Full automation of all four methods is reported, each of which provides [ 11 C]LY2795050 in sufficient radiochemical yield, molar activity, and radiochemical purity for clinical use. The advantages and disadvantages of each radiosynthesis method are compared and contrasted.

Published

2023

2. Development of Positron Emission Tomography Radiotracers for the GABA Transporter 1.

Author

Sowa AR, Brooks AF, Shao X, Henderson BD, Sherman P, Arteaga J, Stauff J, Lee AC, Koeppe RA, Scott PJH, and Kilbourn MR

Subjects

ATP Binding Cassette Transporter, Subfamily B, Member 1 antagonists & inhibitors, Animals, Brain diagnostic imaging, Cyclosporine pharmacology, Enzyme Inhibitors pharmacology, Esters metabolism, Fluorine Radioisotopes, Macaca mulatta, Permeability, Piperidines chemical synthesis, Positron-Emission Tomography, Radiopharmaceuticals chemical synthesis, Rats, Stereoisomerism, Tiagabine metabolism, Blood-Brain Barrier metabolism, Brain metabolism, GABA Plasma Membrane Transport Proteins metabolism, GABA Uptake Inhibitors metabolism, Piperidines metabolism, Radiopharmaceuticals metabolism

Abstract

In vivo positron emission tomography (PET) imaging of the γ-aminobutyric acid (GABA) receptor complex has been accomplished using radiolabeled benzodiazepine derivatives, but development of specific presynaptic radioligands targeting the neuronal membrane GABA transporter type 1 (GAT-1) has been less successful. The availability of new structure-activity studies of GAT-1 inhibitors and the introduction of a GAT-1 inhibitor (tiagabine, Gabatril) into clinical use prompted us to reinvestigate the syntheses of PET ligands for this transporter. Initial synthesis and rodent PET studies of N-[ 11 C]methylnipecotic acid confirmed the low brain uptake of that small and polar molecule. The common design approach to improve blood-brain barrier permeability of GAT-1 inhibitors is the attachment of a large lipophilic substituent. We selected an unsymmetrical bis-aromatic residue attached to the ring nitrogen by a vinyl ether spacer from a series recently reported by Wanner and coworkers. Nucleophilic aromatic substitution of an aryl chloride precursor with [ 18 F]fluoride was used to prepare the desired candidate radiotracer ( R, E/ Z)-1-(2-((4-fluoro-2-(4-[ 18 F]fluorobenzoyl)styryl)oxy)ethyl)piperidine-3-carboxylic acid (( R, E/ Z)-[ 18 F]10). PET studies in rats showed no brain uptake, which was not altered by pretreatment of animals with the P-glycoprotein inhibitor cyclosporine A, indicating efflux by Pgp was not responsible. Subsequent PET imaging studies of ( R, E/ Z)-[ 18 F]10 in rhesus monkey brain showed very low brain uptake. Finally, to test if the free carboxylic acid group was the likely cause of poor brain uptake, PET studies were done using the ethyl ester derivative of ( R, E/ Z)-[ 18 F]10. Rapid and significant monkey brain uptake of the ester was observed, followed by a slow washout over 90 min. The blood-brain barrier permeability of the ester supports a hypothesis that the free acid function limits brain uptake of nipecotic acid-based GAT-1 radioligands, and future radiotracer efforts should investigate the use of carboxylic acid bioisosteres.

Published

2018