<sup>18</sup>F-Labeled Silicon-Based Fluoride Acceptors: Potential Opportunities for Novel Positron Emitting Radiopharmaceuticals

Bernard‐Gauthier, Vadim; Wängler, Carmen; Schirrmacher, Esther; Kostikov, Alexey; Jurkschat, Klaus; Wängler, Bjoern; Schirrmacher, Ralf

doi:10.1155/2014/454503

Cited by 39 publications

(46 citation statements)

References 68 publications

(82 reference statements)

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“…Contrary to carbon, a real pentagonal transition state including hypervalent silicon is formed and assists this substitution. The larger covalent radius of silicon compared to carbon contributes to this nucleophilic substitution [128], which led to the poor kinetic stability of Si-F-bond despite the high thermodynamic stability. Thus, a stabilization of Si-F bond to prevent a nucleophilic attack is only possible by raising the sterical bulkiness of the substituents.…”

Section: Deuteration On Other Parts Of the Molecule To Avoid Degramentioning

confidence: 99%

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Methods to Increase the Metabolic Stability of 18F-Radiotracers

2015

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Abstract:The majority of pharmaceuticals and other organic compounds incorporating radiotracers that are considered foreign to the body undergo metabolic changes in vivo. Metabolic degradation of these drugs is commonly caused by a system of enzymes of low substrate specificity requirement, which is present mainly in the liver, but drug metabolism may also take place in the kidneys or other organs. Thus, radiotracers and all other pharmaceuticals are faced with enormous challenges to maintain their stability in vivo highlighting the importance of their structure. Often in practice, such biologically active molecules exhibit these properties in vitro, but fail during in vivo studies due to obtaining an increased metabolism within minutes. Many pharmacologically and biologically interesting compounds never see application due to their lack of stability. One of the most important issues of radiotracers development based on fluorine-18 is the stability in vitro and in vivo. Sometimes, the metabolism of

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Section: Deuteration On Other Parts Of the Molecule To Avoid Degramentioning

confidence: 99%

“…A summary of applied SiFA building blocks taken from the review by Bernard-Gauthier et al ., 2014 [128]. …”

Section: Deuteration On Other Parts Of the Molecule To Avoid Degramentioning

confidence: 99%

Methods to Increase the Metabolic Stability of 18F-Radiotracers

2015

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“…Much, although not all, of this work has focused on 18 F. 35–38 Indeed, a variety of radiosynthetic methods have been employed to create azide- and alkyne-bearing 18 F-labeled prosthetic groups (Figure 2A). 37,39,40 These tools and the CuAAC reaction have been harnessed with great success in the radiolabeling of a wide variety of vectors, including phosphonium ions, 41 peptides, 42–50 oligonucleotides, 39,47 and proteins. 27,47 This application of the CuAAC reaction is not without its flaws, however.…”

Section: Radiolabeling With Prosthetic Groupsmentioning

confidence: 99%

Click Chemistry and Radiochemistry: The First 10 Years

Meyer¹,

et al. 2016

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The advent of click chemistry has had a profound influence on almost all branches of chemical science. This is particularly true of radiochemistry and the synthesis of agents for positron emission tomography (PET), single photon emission computed tomography (SPECT), and targeted radiotherapy. The selectivity, ease, rapidity, and modularity of click ligations make them nearly ideally suited for the construction of radiotracers, a process that often involves working with biomolecules in aqueous conditions with inexorably decaying radioisotopes. In the following pages, our goal is to provide a broad overview of the first 10 years of research at the intersection of click chemistry and radiochemistry. The discussion will focus on four areas that we believe underscore the critical advantages provided by click chemistry: (i) the use of prosthetic groups for radiolabeling reactions, (ii) the creation of coordination scaffolds for radiometals, (iii) the site-specific radiolabeling of proteins and peptides, and (iv) the development of strategies for in vivo pretargeting. Particular emphasis will be placed on the four most prevalent click reactions—the Cu-catalyzed azide-alkyne cycloaddition (CuAAC), the strainpromoted azide-alkyne cycloaddition (SPAAC), the inverse electron demand Diels-Alder reaction (IEDDA), and the Staudinger ligation—although less well-known click ligations will be discussed as well. Ultimately, it is our hope that this review will not only serve to educate readers but will also act as a springboard, inspiring synthetic chemists and radiochemists alike to harness click chemistry in even more innovative and ambitious ways as we embark upon the second decade of this fruitful collaboration.

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“…SiFAs are a new class of compounds for radiopharmaceutical chemistry where they are used for synthesizing new diagnostic tracer candidates for PET. 9 SiFA chemistry is a radiofluorination strategy for fast and efficient radiolabeling of higher molecular weight constructs such as peptides, proteins, or nanoparticles that accumulate to tumors by enhanced permeability and retention (EPR) effect 10 , 11 or by targeted strategies. 12 − 14 Recently, a compound radiolabeled with SiFA chemistry, a somatostatin receptor-2 targeting peptide 18 F-SiFA lin -TATE, has entered clinical trials.…”

Section: Introductionmentioning

confidence: 99%

Metabolism of a Bioorthogonal PET Tracer Candidate [¹⁹F/¹⁸F]SiFA-Tetrazine in Mouse Liver Microsomes: Biotransformation Pathways and Defluorination Investigated by UHPLC-HRMS

et al. 2020

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Organofluorosilicon based 18 F-radiolabeling is an efficient method for incorporating fluorine-18 into 18 F-radiopharmaceuticals for positron emission tomography (PET) by 19 F/ 18 F isotopic exchange (IE). The first PET radiopharmaceutical, 18 F-SiFA lin -TATE, radiolabeled with a silicon-based [ 18 F]fluoride acceptor (SiFA), namely, a para-substituted di- tert -butyl[ 18 F]fluorosilylbenzene, has entered clinical trials, and is paving the way for other potential [ 18 F]SiFA-labeled radiopharmaceuticals for diagnostic use. In this study, we report the in vitro metabolism of an oxime-linked SiFA tetrazine (SiFA–Tz), a new PET-radiotracer candidate, recently evaluated for pretargeted PET imaging and macromolecule labeling. Metabolism of SiFA–Tz was studied in mouse liver microsomes (MLM) for elucidating its major biotransformation pathways. Nontargeted screening by ultrahigh performance liquid chromatography high-resolution mass spectrometry (UHPLC-HRMS) was utilized for detection of unknown metabolites. The oxime bond between the SiFA and Tz groups forms two geometric ( E / Z ) isomers, which underwent the same biotransformations, but unexpectedly with different kinetics. In total, nine proposed metabolites of SiFA–Tz from phase I and II reactions were detected, five of which were defluorinated in MLMs, elucidating the metabolic pathway leading to previously reported defluorination of [ 18 F]SiFA–Tz in vivo . Based on the HRMS studies a biotransformation pathway is proposed: hydroxylation (+O) to tert -butyl group adjacent to the silicon, followed by oxidative defluorination (+OH/-F) cleaving the fluorine off the silicon. Interestingly, eight proposed metabolites of a reduced dihydrotetrazine analogue, SiFA–H 2 Tz, from phase I and II reactions were additionally detected. To the best of our knowledge, this is the first reported comprehensive investigation of enzyme mediated metabolic pathway of tetrazines and para-substituted di- tert -butylfluorosilylbenzene fluoride acceptors, providing novel structural information on the biotransformation and fragmentation patterns of radiotracers bearing these structural motifs. By investigating the metabolism preceding defluorination, structurally optimized new SiFA compounds can be designed for expanding the portfolio of efficient 19 F/ 18 F isotopic exchange labeling probes for PET imaging.

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¹⁸F-Labeled Silicon-Based Fluoride Acceptors: Potential Opportunities for Novel Positron Emitting Radiopharmaceuticals

Cited by 39 publications

References 68 publications

Methods to Increase the Metabolic Stability of 18F-Radiotracers

Methods to Increase the Metabolic Stability of 18F-Radiotracers

Click Chemistry and Radiochemistry: The First 10 Years

Metabolism of a Bioorthogonal PET Tracer Candidate [¹⁹F/¹⁸F]SiFA-Tetrazine in Mouse Liver Microsomes: Biotransformation Pathways and Defluorination Investigated by UHPLC-HRMS

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18F-Labeled Silicon-Based Fluoride Acceptors: Potential Opportunities for Novel Positron Emitting Radiopharmaceuticals

Cited by 39 publications

References 68 publications

Methods to Increase the Metabolic Stability of 18F-Radiotracers

Methods to Increase the Metabolic Stability of 18F-Radiotracers

Click Chemistry and Radiochemistry: The First 10 Years

Metabolism of a Bioorthogonal PET Tracer Candidate [19F/18F]SiFA-Tetrazine in Mouse Liver Microsomes: Biotransformation Pathways and Defluorination Investigated by UHPLC-HRMS

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¹⁸F-Labeled Silicon-Based Fluoride Acceptors: Potential Opportunities for Novel Positron Emitting Radiopharmaceuticals

Metabolism of a Bioorthogonal PET Tracer Candidate [¹⁹F/¹⁸F]SiFA-Tetrazine in Mouse Liver Microsomes: Biotransformation Pathways and Defluorination Investigated by UHPLC-HRMS