Your search keyword '"Mossel, Pascalle"' showing total 8 results

1. Non-invasive kinetic modelling approaches for quantitative analysis of brain PET studies

Author

van der Weijden, Chris W. J., Mossel, Pascalle, Bartels, Anna L., Dierckx, Rudi A. J. O., Luurtsema, Gert, Lammertsma, Adriaan A., Willemsen, Antoon T. M., and de Vries, Erik F. J.

Published

2023

2. First clinical assessment of [18F]MC225, a novel fluorine-18 labelled PET tracer for measuring functional P-glycoprotein at the blood–brain barrier

Author

Toyohara, Jun, Sakata, Muneyuki, Ishibashi, Kenji, Mossel, Pascalle, Imai, Masamichi, Wagatsuma, Kei, Tago, Tetsuro, Imabayashi, Etsuko, Colabufo, Nicola A., Luurtsema, Gert, and Ishii, Kenji

Published

2021

3. Cardiac PET Imaging of ATP Binding Cassette (ABC) Transporters: Opportunities and Challenges.

Author

Liu, Wanling, Mossel, Pascalle, Schwach, Verena, Slart, Riemer H. J. A., and Luurtsema, Gert

Subjects

*POSITRON emission tomography, *CARDIAC imaging, *ATP-binding cassette transporters, *DRUG development, *MEMBRANE proteins, *ADENOSINE triphosphate, *INTRACELLULAR membranes

Abstract

Adenosine triphosphate binding cassette (ABC) transporters are a broad family of membrane protein complexes that use energy to transport molecules across cells and/or intracellular organelle lipid membranes. Many drugs used to treat cardiac diseases have an affinity for these transporters. Among others, P-glycoprotein (P-gp) plays an essential role in regulating drug concentrations that reach cardiac tissue and therefore contribute to cardiotoxicity. As a molecular imaging modality, positron emission tomography (PET) has emerged as a viable technique to investigate the function of P-gp in organs and tissues. Using PET imaging to evaluate cardiac P-gp function provides new insights for drug development and improves the precise use of medications. Nevertheless, information in this field is limited. In this review, we aim to examine the current applications of ABC transporter PET imaging and its tracers in the heart, with a specific emphasis on P-gp. Furthermore, the opportunities and challenges in this novel field will be discussed. [ABSTRACT FROM AUTHOR]

Published

2023

4. PET Imaging of ABC Transporters at the Blood-Brain Barrier

Author

Garcia Varela, Lara, Mossel, Pascalle, Benadiba, Marcel, Savolainen, Heli, Colabufo, Nicola Antonio, Windhorst, Albert D., Elsinga, Philip H., van Waarde, Aren, Luurtsema, Gert, Dierckx, Rudi, Otte, Andreas, de Vries, Erik, Lammertsma, Adriaan, Guided Treatment in Optimal Selected Cancer Patients (GUTS), ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE), and Molecular Neuroscience and Ageing Research (MOLAR)

Subjects

Kinetic modelling, Radiochemistry, POSITRON EMISSION TOMOGRAPHY, ABC Transporters, P-GLYCOPROTEIN, Brain imaging, QUANTIFICATION, IMAGING, HUMAN BRAIN

Abstract

The function of ATP-binding cassette (ABC) transporters at the blood-brain barrier (BBB) is to protect the brain from toxic compounds. Additionally, they play a crucial role in the onset and progression of several central nervous system (CNS) diseases as well as in drug resistance. Many compounds were identified as substrates, inhibitors, inducers, or activators for ABC transporters, causing important drug-drug interactions. PET imaging represents an excellent tool for assessing the function and expression of ABC transporters. Over the last years, many PET tracers with different characteristics have been developed, mainly for measuring P-glycoprotein (P-gp) function at the BBB. Although (R)-[11C]verapamil or [11C]N-desmethylloperamide are considered as the “gold standard” P-gp tracers, they have several drawbacks such as its high affinity to P-gp which limits their use for assessing P-gp increased function. Therefore, PET tracers with lower affinity to the transporter have been developed and studied in different species. The assessment of ABC transporters by PET imaging can provide new insight into the physiology and pathophysiology of different CNS diseases and may open new avenues for therapies. Moreover, PET can be used for screening the affinity of new entities toward various ABC transporters and thus enhance the development of CNS drugs.

Published

2021

5. First clinical assessment of [18F]MC225, a novel fluorine-18 labelled PET tracer for measuring functional P-glycoprotein at the blood–brain barrier.

Author

Toyohara, Jun, Sakata, Muneyuki, Ishibashi, Kenji, Mossel, Pascalle, Imai, Masamichi, Wagatsuma, Kei, Tago, Tetsuro, Imabayashi, Etsuko, Colabufo, Nicola A., Luurtsema, Gert, and Ishii, Kenji

Abstract

Objective: 5-(1-(2-[18F]fluoroethoxy))-[3-(6,7-dimethoxy-3,4-dihydro-1H-isoquinolin-2-yl)-propyl]-5,6,7,8-tetrahydronaphthalen ([18F]MC225) is a selective substrate for P-glycoprotein (P-gp), possessing suitable properties for measuring overexpression of P-gp in the brain. This is the first-in-human study to examine safety, radiation dosimetry and P-gp function at the blood–brain barrier (BBB) of [18F]MC225 in healthy subjects. Methods: [18F]MC225 biodistribution and dosimetry were determined in 3 healthy male subjects, using serial 2 h and intermittent 4 and 6 h whole-body PET scans acquired after [18F]MC225 injection. Dynamic [18F]MC225 brain PET (90 min) was obtained in 5 healthy male subjects. Arterial blood was sampled at various time intervals during scanning and the fraction of unchanged [18F]MC225 in plasma was determined. T1-weighted MRI was performed for anatomical coregistration. Total distribution volume (VT) was estimated using 1- and 2-tissue-compartment models (1-TCM and 2-TCM, respectively). VT was also estimated using the Logan graphical method (Logan plot) (t* = 20 min). Surrogate parameters without blood sampling (area-under the curve [AUC] of regional time–activity curves [TACs] and negative slope of calculated TACs) were compared with the VT values. Results: No serious adverse events occurred throughout the study period. Although biodistribution implied hepatobiliary excretion, secretion of radioactivity from liver to small intestine through the gallbladder was very slow. Total renal excreted radioactivity recovered during 6 h after injection was < 2%ID. Absorbed dose was the highest in the pancreas (mean ± SD, 203 ± 45 μGy/MBq) followed by the liver (83 ± 11 μGy/MBq). Mean effective dose with and without urination was 17 ± 1 μSv/MBq. [18F]MC225 readily entered the brain, distributing homogeneously in grey matter regions. 2-TCM provided lower Akaike information criterion scores than did 1-TCM. VT estimated by Logan plot was well correlated with that of 2-TCM (r2 > 0.9). AUCs of TACs were positively correlated with VT (2-TCM) values (r2: AUC0-60 min = 0.61, AUC0-30 min = 0.62, AUC30-60 min = 0.59, p < 0.0001). Negative slope of SUV TACs was negatively correlated with VT (2-TCM) values (r2 = 0.53, p < 0.0001). Conclusions: This initial evaluation indicated that [18F]MC225 is a suitable and safe PET tracer for measuring P-gp function at the BBB. [ABSTRACT FROM AUTHOR]

Published

2021

6. Evaluation of P-glycoprotein function at the blood–brain barrier using [18F]MC225-PET.

Author

Mossel, Pascalle, Garcia Varela, Lara, Arif, Wejdan M., van der Weijden, Chris W. J., Boersma, Hendrikus H., Willemsen, Antoon T. M., Boellaard, Ronald, Elsinga, Philip H., Borra, Ronald J. H., Colabufo, Nicola A., Toyohara, Jun, de Deyn, Peter Paul, Dierckx, Rudi A. J. O., Lammertsma, Adriaan A., Bartels, Anna L., and Luurtsema, Gert

Subjects

*BLOOD-brain barrier, *POSITRON emission tomography

Abstract

[ SP 18 sp F]MC225 is a weaker P-gp substrate and has shown higher brain uptake than I (R)- i [ SP 11 sp C]verapamil at baseline in preclinical studies [[2]]. P-glycoprotein (P-gp) is an ATP-dependent efflux transporter located at the blood-brain barrier (BBB), involved in the transport of a variety of neurotoxic substances out of the brain. Evaluation of P-glycoprotein function at the blood-brain barrier using [18F]MC225-PET. [Extracted from the article]

Published

2021

7. Oral administration of PET tracers: Current status.

Author

Salvi de Souza, Giordana, Mantovani, Dimitri B.A., Mossel, Pascalle, Haarman, Bartholomeus C.M., Marques da Silva, Ana Maria, Boersma, Hendrikus H., Furini, Cristiane R.G., Lammertsma, Adriaan A., Tsoumpas, Charalampos, and Luurtsema, Gert

Subjects

*ORAL drug administration, *GASTROINTESTINAL system, *POSITRON emission tomography, *PHARMACOKINETICS, *MAGNETIC resonance imaging, *DRUG absorption

Abstract

The oral route is the most widely used and preferable way of drug administration. Several pharmacokinetic processes play a role in the distribution of administered drugs. Therefore, accurate quantification of absorption, distribution, metabolism, excretion, and characterisation of drug kinetics after oral administration is extremely important for developing new human drugs. In vivo methods, such as gamma-scintigraphy, magnetic resonance imaging (MRI), and positron emission tomography (PET), have been used to analyse gastrointestinal tract (GIT) absorption behaviour. This scoping review provides an overview of PET studies that used oral tracer administration. A systematic literature search was performed using PubMed, EMBASE, Scopus, Science Direct, and Web of Science databases. Extensive variation between these studies was seen concerning acquisition protocols, quantification methods, and pharmacokinetic outcome parameters. Studies in humans indicate that it takes 10 to 30 min for the tracer to be in the intestine and about 100 min to reach its maximum concentration in the brain. In rodent studies, different pharmacokinetic parameters for the brain, blood, and GIT were estimated, showing the potential of PET to measure the absorption and distribution of drugs and pharmaceuticals non-invasively. Finally, regarding radiation protection, oral administration has a higher absorbed dose in GIT and, consequently, a higher effective dose. However, with the recent introduction of Long Axial Field of View (LAFOV) PET scanners, it is possible to reduce the administered dose, making oral administration feasible for routine clinical studies. [Display omitted] • This route of administration results in delayed plasma peaks dependent on the tracer, population, fasting, use of anaesthetics, and GIT motility. • The approach can have clinical implications for therapeutic strategies, drug dosages, and the treatment of GIT diseases. [ABSTRACT FROM AUTHOR]

Published

2023

8. [18F]MC225 PET for the dose-response assessment of tariquidar inhibition of blood-brain barrier P-glycoprotein function in vivo

Author

Garcia Varela, Lara, Mossel, Pascalle, Aguiar, Pablo, Vazquez Matias, Daniel, van Waarde, Aren, Willemsen, Antoon, Bartels, Anna L., Dierckx, Rudi, Elsinga, Philip H., Luurtsema, Gert, ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE), Molecular Neuroscience and Ageing Research (MOLAR), and Guided Treatment in Optimal Selected Cancer Patients (GUTS)

Subjects

BLOOD-BRAIN BARRIER, POSITRON EMISSION TOMOGRAPHY, DOSE-RESPONSE CURVES, P-GLYCOPROTEIN, TARIQUIDAR, MC225

Abstract

Aim/Introduction: At the blood-brain barrier (BBB), P-glycoprotein (P-gp) is an efflux transporter that maintains homeostasis by protecting the brain from neurotoxic substances. BBB P-gp function may not be completely blocked but partially due to the effect of different Central-Nervous-System drugs or in patients with neurodegenerative diseases [1]. [18F]MC225 is a weak P-gp substrate tracer that may show higher sensitivity to detect small changes in the P-gp function than previously developed P-gp tracers [2,3]. This study aims to explore the sensitivity of [18F]MC225 to measure the effect of different doses of tariquidar (a P-gp inhibitor) and find the most appropriate fit to the doseresponse curve. Materials and Methods: Twenty-three rats were divided into seven groups (n=3-4) and injected with different doses of tariquidar (0 (control), 0.75, 1.5, 3, 6, 8, and 12mg/kg). Tariquidar was administered intravenously 30 min before the PET acquisition with arterial sampling. Tissue and blood data were fitted to a 1-Tissue-Compartment-Model to obtain the kinetic parameters K1 and VT, which allow the estimation of the P-gp function [2]. Dose-response curve was fitted to different models using GraphPad Prism v6. ANOVA and post-hoc analyses were performed to explore the differences in K1 and VT among groups. Results: The best fit was obtained using the four-parameters sigmoidal curve. The IC50 was 2.18±0.27 mg/kg, the minimum K1 value was 0.25 (0.15-0.36 95%CI) and the maximum K1 value was 0.99 (0.90-1.08 95%CI), which was reached with a dose of 6mg/kg. K1 values increased from 0.25±0.03 (control) to 0.39±0.14 in the 1.5mg/kg group, however, significant differences compared to controls were only found from a dose of 3 mg/kg on (K1=0.82±0.16; p=0.001). Similar results were obtained using the VT to estimate the P-gp function. Conclusion: The dose-response curve using either K1 or VT provided similar results. A tariquidar dose of 6mg/kg completely inhibited the P-gp function. A significant increase of K1 values was detected at 3mg/kg dose and a trend to increase was already seen after 1.5mg/kg. This study shows that [18F]MC225 seems an adequate tracer to measure small changes in the P-gp function in vivo and thus may be useful in Alzheimer and drug resistance studies where P-gp function can be partially altered. References: 1. Wanek T, et al. Mol Pharm. 2015;12:3214-252. Savolainen H, et al. J Cereb Blood Flow Metab. 2017;37:1286-983. Bauer M, et al. Clin Pharmacol Ther. 2019;105:1061-4