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@ARTICLE{Craig:872686,
author = {Craig, Austin and Kolks, Niklas and Urusova, Elizaveta and
Zischler, Johannes and Neumaier, Bernd and Zlatopolskiy,
Boris},
title = {{T}he efficient preparation of radiolabeled aromatic amino
acids via {C}u‐mediated radiofluorination of
{N}i‐complexes},
journal = {Journal of labelled compounds and radiopharmaceuticals},
volume = {62},
number = {S1},
issn = {0022-2135},
address = {New York, NY [u.a.]},
publisher = {Wiley},
reportid = {FZJ-2020-00177},
pages = {S118},
year = {2019},
abstract = {Objectives: The aim of this work was to develop a versatile
procedure for the preparation of 18F‐labeled aromatic
amino acids (AAA) via alcohol‐enhanced Cu‐mediated
radiofluorination using Ni‐BPX auxiliaries as
easily‐removable dual‐protecting group functionalities.
Additionally, the use Ni‐BPA‐Ala complexes were
investigated in order to access a number of synthetically
challenging α‐Me‐AAA tracers. Furthermore, the
implementation of the radiosynthetic methods into automated
modules was carried out in order to facilitate the
production of these AAA tracers for biological
evaluation.Methods: The Bpin‐substituted precursors of
radiofluorinated AAAs and α‐Me AAAs were prepared by
alkylation of (S)‐Ni‐BPB‐Gly and
(S)‐Ni‐BPA‐(RS)‐Ala with the corresponding
Bpin‐substituted benzyl bromides. Radiolabeling was
carried out according to the protocol for alcohol‐enhanced
Cu‐mediated radiofluorination as follows:1 [18F]F‐ was
loaded onto a QMA‐cartridge which was subsequently washed
with MeOH; [18F]F‐ was eluted with Et4NHCO3, solvent was
evaporated, the residue was taken up in to a solution of Cu
(py)4(OTf)2 and precursor in DMF/nBuOH (2:1), and the
reaction mixture was stirred under air at 110 °C for 10
min. The evaporation of the DMA/nBuOH was followed by
deprotection using 12 M HCl at 110 °C for 15 min. Finally,
the desired tracers were isolated by semi‐preparative
HPLC.Results: The appropriate BPin‐substituted
Ni‐BPX‐AAA complexes were prepared from commercially
available materials in $10–72\%$ yield over 1–4 steps.
Radiolabeled Ni complexes containing 2–4‐[18F]FPhe,
2–4‐aMe‐[18F]FPhe, 6‐[18F]FMT, aMe‐6‐[18F]FMT,
4‐[18F]FTrp and 2‐[18F] FTyr residues were synthesized
in RCCs of $50–95\%.$ The purified tracers were isolated
in n.d.c RCYs of $15–40\%$ and in excellent radiochemical
and enantiomeric purity. Radiosyntheses of 3‐[18F]FPhe,
4‐[18F]FPhe and 4‐[18F]FTrp were implemented to an
automated module furnishing tracers in n.d.c RCYs of $10\%,$
$15\%$ and $17\%,$ respectively, within 75–80
min.Conclusions: Alcohol‐enhanced Cu‐mediated
radiofluorination of BPin substituted Ni‐BPX‐AAA
complexes is a simple, yet powerful method for the fast
production of structurally diverse radiolabeled AAAs and
α‐methyl substituted AAAs. The attractiveness of the
procedure is highlighted by the accessibility of
radiolabeling precursors, high RCYs and easy implementation
into an automated module.},
month = {May},
date = {2019-05-26},
organization = {The 23rd International Symposium on
Radiopharmaceutical Sciences, Beijing
(China), 26 May 2019 - 31 May 2019},
cin = {INM-5},
ddc = {610},
cid = {I:(DE-Juel1)INM-5-20090406},
pnm = {573 - Neuroimaging (POF3-573)},
pid = {G:(DE-HGF)POF3-573},
typ = {PUB:(DE-HGF)16},
url = {https://juser.fz-juelich.de/record/872686},
}
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