Synthesis of novel ligands for neuroinflammation imaging using Positron Emission Tomography

La neuroinflammation joue un rôle important dans de nombreuses maladies neurodégénératives telles que la maladie d’Alzheimer, Parkinson, ou encore la sclérose en plaques. De récents développements en imagerie moléculaire permettent aujourd’hui un meilleur diagnostique et un meilleur suivi thérapeutique de ces maladies. Parmi les techniques d’imagerie dont nous disposons actuellement, la Tomographie par Emission de Positions (TEP) et Tomographie par Emission Mono Photonique (TEMP) jouent un rôle important de par leur haute sensibilité et leurs aspects quantitatifs. L’objectif de ma thèse est de développer de nouveaux ligands et radioligands dédiés à l’imagerie de cibles spécifiques impliquées dans les processus de neuroinflammation. Pour ce faire, la TEP et ses émetteurs de positons à vie brève associés (notamment le fluor-18 ; T1/2 : 109.8 min) constituent un outil de choix. Le projet est divisé en deux sections principales. La première est dédiée au développement de ligands ciblant la protéine de Translocation 18 kDa (TSPO). Cette protéine est aujourd’hui reconnue comme un biomarqueur précoce des processus neuroinflammatoires, et de nombreux ligands ont déjà été synthétisés pour cette cible. Le plus anciens d’entre eux est le PK11195 appartenant à la famille des isoquinoléines, qui a été marqué au carbone-11 à la fin des années 80. Plus récemment, d’autres familles de composés ont vu le jour, et notamment la familles des pyrazolopyrimidines avec le [11C]DPA-713, ainsi que celle des pyridazinoindoles avec le [11C]SSR180575. A travers cette première partie de ma thèse, l’objectif est de synthétiser et de caractériser in vitro de nouveaux ligands dérivés des deux composés leaders de ces deux familles. Les précurseurs de marquage correspondant ont également été synthétisés pour les composés les plus prometteurs, permettant ainsi un radiomarquage au fluor-18. Certains résultats ont par ailleurs été présentés lors d’un congrès international (21st International Symposium on Radiopharmaceutical Sciences (Columbia, MO, USA – Mai 26-31, 2015)). La seconde partie de ma thèse est dédiée au développement de ligands pour des cibles alternatives à la TSPO, qui sont les récepteurs cannabinoïdes de type 2 (CB2R), et les récepteurs purinergiques P2Y12 et P2Y14. Ces nouvelles cibles, récemment émergées présentent un fort potentiel pour de nouvelles opportunités en imagerie. Une nouvelle série de sept composés a par ailleurs déjà été synthétisée en ce qui concerne le CB2R. Les précurseurs des molécules les plus prometteuses ont également été préparés. La synthèse des ligands dédiés aux récepteurs purinergiques a été initiée, et un premier couple référence /précurseur a été obtenu.Neuroinflammation plays an important role in many neurodegenerative diseases (Alzheimer, Parkinson, Multiple sclerosis …) and recent developments in molecular imaging provide today new insights into the diagnostic and the treatement managment of these diseases. Among the existing imaging techniques, the highly sensitive and quantitative nuclear modalities SPECT (single photon emission computed tomography) but especially PET (positron emission tomography) play key roles. My PhD program is devoted to the design and synthesis of novel radioligands, all dedicated to the imaging of specific targets and processes linked to neuroinflammation. For this, PET and the short-lived positron-emitter fluorine-18 (T1/2: 109.8 min) remain the main focuses. The project has been divided into two sections, the first one concentrates on the development of novel ligands targeting the Translocator Protein 18 kDa (TSPO). Indeed, this target is today recognized as an early biomarker of neuroinflammatory processes and PK11195, an isoquinoline carboxamide labelled with carbon-11, was, in the late 80’s, the first reported PET-radioligand. More recently, new compounds, all belonging to different chemical classes, have emerged and notably the pyrazolopyrimidine acetamide [11C]DPA-713 and the pyridazinoindole acetamide [11C]SSR180575. Within the first section of my PhD, novel derivatives of both DPA-713 and SSR180575 have been synthesized and in vitro characterized. Dedicated precursors for labelling were also developed for the most promising candidates, and radiolabelling has been performed. Some results have been presented at the 21st International Symposium on Radiopharmaceutical Sciences (Columbia, MO, USA – May 26-31, 2015).The second part of my PhD, deals with the development of ligands for alternative targets to the TSPO, like the type-2 cannabinoid receptor (CB2R) and the purinergic P2Y14 / P2Y12 receptors, the latter emerging today as a hot topic for imaging opportunities. Up to now, a series of seven compounds targeting the CB2R has been successfully synthetized and in vitro characterized. Dedicated precursors of the most promising compounds have also been prepared and labelling will be shortly performed. The synthesis of ligands targeting the purinergic receptors has also been initiated and a first couple of reference / precursor has been obtained for the P2Y12R

Synthèse de nouveaux ligands pour l'imagerie de la neuroinflammation par tomographie par émission de positons

Neuroinflammation plays an important role in many neurodegenerative diseases (Alzheimer, Parkinson, Multiple sclerosis …) and recent developments in molecular imaging provide today new insights into the diagnostic and the treatement managment of these diseases. Among the existing imaging techniques, the highly sensitive and quantitative nuclear modalities SPECT (single photon emission computed tomography) but especially PET (positron emission tomography) play key roles. My PhD program is devoted to the design and synthesis of novel radioligands, all dedicated to the imaging of specific targets and processes linked to neuroinflammation. For this, PET and the short-lived positron-emitter fluorine-18 (T1/2: 109.8 min) remain the main focuses. The project has been divided into two sections, the first one concentrates on the development of novel ligands targeting the Translocator Protein 18 kDa (TSPO). Indeed, this target is today recognized as an early biomarker of neuroinflammatory processes and PK11195, an isoquinoline carboxamide labelled with carbon-11, was, in the late 80’s, the first reported PET-radioligand. More recently, new compounds, all belonging to different chemical classes, have emerged and notably the pyrazolopyrimidine acetamide [11C]DPA-713 and the pyridazinoindole acetamide [11C]SSR180575. Within the first section of my PhD, novel derivatives of both DPA-713 and SSR180575 have been synthesized and in vitro characterized. Dedicated precursors for labelling were also developed for the most promising candidates, and radiolabelling has been performed. Some results have been presented at the 21st International Symposium on Radiopharmaceutical Sciences (Columbia, MO, USA – May 26-31, 2015).The second part of my PhD, deals with the development of ligands for alternative targets to the TSPO, like the type-2 cannabinoid receptor (CB2R) and the purinergic P2Y14 / P2Y12 receptors, the latter emerging today as a hot topic for imaging opportunities. Up to now, a series of seven compounds targeting the CB2R has been successfully synthetized and in vitro characterized. Dedicated precursors of the most promising compounds have also been prepared and labelling will be shortly performed. The synthesis of ligands targeting the purinergic receptors has also been initiated and a first couple of reference / precursor has been obtained for the P2Y12R.La neuroinflammation joue un rôle important dans de nombreuses maladies neurodégénératives telles que la maladie d’Alzheimer, Parkinson, ou encore la sclérose en plaques. De récents développements en imagerie moléculaire permettent aujourd’hui un meilleur diagnostique et un meilleur suivi thérapeutique de ces maladies. Parmi les techniques d’imagerie dont nous disposons actuellement, la Tomographie par Emission de Positions (TEP) et Tomographie par Emission Mono Photonique (TEMP) jouent un rôle important de par leur haute sensibilité et leurs aspects quantitatifs. L’objectif de ma thèse est de développer de nouveaux ligands et radioligands dédiés à l’imagerie de cibles spécifiques impliquées dans les processus de neuroinflammation. Pour ce faire, la TEP et ses émetteurs de positons à vie brève associés (notamment le fluor-18 ; T1/2 : 109.8 min) constituent un outil de choix. Le projet est divisé en deux sections principales. La première est dédiée au développement de ligands ciblant la protéine de Translocation 18 kDa (TSPO). Cette protéine est aujourd’hui reconnue comme un biomarqueur précoce des processus neuroinflammatoires, et de nombreux ligands ont déjà été synthétisés pour cette cible. Le plus anciens d’entre eux est le PK11195 appartenant à la famille des isoquinoléines, qui a été marqué au carbone-11 à la fin des années 80. Plus récemment, d’autres familles de composés ont vu le jour, et notamment la familles des pyrazolopyrimidines avec le [11C]DPA-713, ainsi que celle des pyridazinoindoles avec le [11C]SSR180575. A travers cette première partie de ma thèse, l’objectif est de synthétiser et de caractériser in vitro de nouveaux ligands dérivés des deux composés leaders de ces deux familles. Les précurseurs de marquage correspondant ont également été synthétisés pour les composés les plus prometteurs, permettant ainsi un radiomarquage au fluor-18. Certains résultats ont par ailleurs été présentés lors d’un congrès international (21st International Symposium on Radiopharmaceutical Sciences (Columbia, MO, USA – Mai 26-31, 2015)). La seconde partie de ma thèse est dédiée au développement de ligands pour des cibles alternatives à la TSPO, qui sont les récepteurs cannabinoïdes de type 2 (CB2R), et les récepteurs purinergiques P2Y12 et P2Y14. Ces nouvelles cibles, récemment émergées présentent un fort potentiel pour de nouvelles opportunités en imagerie. Une nouvelle série de sept composés a par ailleurs déjà été synthétisée en ce qui concerne le CB2R. Les précurseurs des molécules les plus prometteuses ont également été préparés. La synthèse des ligands dédiés aux récepteurs purinergiques a été initiée, et un premier couple référence /précurseur a été obtenu

Synthesis and in vitro characterization of novel fluorinated derivatives of the translocator protein 18 kDa ligand CfO-DPA-714

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The Piancatelli rearrangement of non-symmetrical furan-2,5-dicarbinols for the synthesis of highly functionalized cyclopentenones

Piancatelli rearrangement on substituted non-symmetrical furan-2,5-dicarbinols has been developed using an effective combination of microwave activation and Lewis acid catalyst.</p

Novel Pyrazolo[1,5- a ]pyrimidines as Translocator Protein 18 kDa (TSPO) Ligands: Synthesis, in Vitro Biological Evaluation, [ 18 F]-Labeling, and in Vivo Neuroinflammation PET Images

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From Structure–Activity Relationships on Thiazole Derivatives to the In Vivo Evaluation of a New Radiotracer for Cannabinoid Subtype 2 PET Imaging

International audienceAbstract Nowadays, high‐resolution mass spectrometry is widely used for metabolomic studies. Thanks to its high sensitivity, it enables the detection of a large range of metabolites. In metabolomics, the continuous quest for a metabolite identification as complete and accurate as possible has led during the last decade to an ever increasing development of public MS databases (including LC‐MS data) concomitantly with bioinformatic tool expansion. To facilitate the annotation process of MS profiles obtained from biological samples, but also to ease data sharing, exchange, and exploitation, the standardization and harmonization of the way to describe and annotate mass spectra seemed crucial to us. Indeed, under electrospray (ESI) conditions, a single metabolite does not produce a unique ion corresponding to its protonated or deprotonated form but could lead to a complex mixture of signals. These MS signals result from the existence of different natural isotopologues of the same compound and also to the potential formation of adduct ions, homomultimeric and heteromultimeric ions, fragment ions resulting from “prompt” in‐source dissociations. As a joint reflection process within the French Infrastructure for Metabolomics and Fluxomics (MetaboHUB) and with the purpose of developing a robust and exchangeable annotated MS database made from pure reference compounds (chemical standards) analysis, it appeared to us that giving the metabolomics community some clues to standardize and unambiguously annotate each MS feature was a prerequisite to data entry and further efficient querying of the mass spectral database. The use of a harmonized notation is also mandatory for interlaboratory MS data exchange. Additionally, thorough description of the variety of MS signals arising from the analysis of a unique metabolite might provide greater confidence on its annotation

[18F]F-DPA for the detection of activated microglia in a mouse model of Alzheimer's disease

International audienceIntroduction: Neuroinflammation is associated with several neurological disorders, including Alzheimer's disease (AD). The translocator protein 18 kDa (TSPO), due to its overexpression during microglial activation and relatively low levels in the brain under normal neurophysiological conditions, is commonly used as an in vivo biomarker for neuroinflammation. Reported here is the preclinical evaluation of [ 18 F]F-DPA, a promising new TSPO-specific radioligand, as a tool for the detection of activated microglia at different ages in the APP/PS1-21 mouse model of AD and a blocking study to determine the specificity of the tracer. Methods: [ 18 F]F-DPA was synthesised by the previously reported electrophilic 18 F-fluorination methodology. In vivo PET and ex vivo brain autoradiography were used to observe the tracer distribution in the brains of APP/PS1-21 and wildtype mice at different ages (4.5-24 months). The biodistribution and degree of metabolism of [ 18 F]F-DPA were analysed and the specificity of [ 18 F]F-DPA for its target was determined by pre-treatment with PK11195. Results: The in vivo PET imaging and ex vivo brain autoradiography data showed that [ 18 F]F-DPA uptake in the brains of the transgenic animals increased with age, however, there was a drop in the tracer uptake at 19 mo. Despite the slight increase in [ 18 F]F-DPA uptake with age in healthy animal brains, significant differences between wildtype and transgenic animals were seen in vivo at 9 months and ex vivo already at 4.5 months. The specificity study demonstrated that PK11195 can be used to significantly block [ 18 F]F-DPA uptake in all the brain regions studied. Conclusions: In vivo time activity curves plateaued at approximately 20-40 min suggesting that this is the optimal imaging time. Significant differences in vivo are seen at 9 and 12 mo. Due to the higher resolution, ex vivo autoradiography with [ 18 F]F-DPA can be used to visualise activated microglia at an early stage of AD pathology

Novel Pyrazolo[1,5‑<i>a</i>]pyrimidines as Translocator Protein 18 kDa (TSPO) Ligands: Synthesis, <i>in Vitro</i> Biological Evaluation, [¹⁸F]-Labeling, and <i>in Vivo</i> Neuroinflammation PET Images

A series of novel pyrazolo­[1,5-<i>a</i>]­pyrimidines, closely related to <i>N</i>,<i>N</i>-diethyl-2-(2-(4-(2-fluoroethoxy)­phenyl)-5,7-dimethylpyrazolo­[1,5-<i>a</i>]­pyrimidin-3-yl)­acetamide (<b>2</b>, DPA-714), were synthesized and biologically <i>in vitro</i> evaluated for their potential to bind the translocator protein 18 kDa (TSPO), a protein today recognized as an early biomarker of neuroinflammatory processes. This series is composed of fluoroalkyl- and fluoroalkynyl- analogues, prepared from a common iodinated intermediate via Sonogashira coupling reactions. All derivatives displayed subnanomolar affinity for the TSPO (0.37 to 0.86 nM), comparable to that of <b>2</b> (0.91 nM). Two of them were radiolabeled with fluorine-18, and their biodistribution was investigated by <i>in vitro</i> autoradiography and positron emission tomography (PET) imaging on a rodent model of neuroinflammation. Brain uptake and local accumulation of both compounds in the AMPA-mediated lesion confirm their potential as <i>in vivo</i> PET-radiotracers. In particular, [¹⁸F]<b>23</b> exhibited a significantly higher ipsi- to contralateral ratio at 60 min than the parent molecule [¹⁸F]<b>2</b> <i>in vivo</i>