Your search keyword '"Madonia, J"' showing total 3 results

1. 18 F-PI-2620 Tau PET Improves the Imaging Diagnosis of Progressive Supranuclear Palsy.

Author

Messerschmidt K, Barthel H, Brendel M, Scherlach C, Hoffmann KT, Rauchmann BS, Rullmann M, Marek K, Villemagne VL, Rumpf JJ, Saur D, Schroeter ML, Schildan A, Patt M, Beyer L, Song M, Palleis C, Katzdobler S, Fietzek UM, Respondek G, Scheifele M, Nitschmann A, Zach C, Barret O, Madonia J, Russell D, Stephens AW, Koglin N, Roeber S, Herms J, Bötzel K, Bartenstein P, Levin J, Seibyl JP, Höglinger G, Classen J, and Sabri O

Subjects

Humans, tau Proteins, Magnetic Resonance Imaging methods, Atrophy, Supranuclear Palsy, Progressive diagnosis

Abstract

Progressive supranuclear palsy (PSP) is a 4-repeat tauopathy movement disorder that can be imaged by the 18 F-labeled tau PET tracer 2-(2-([ 18 F]fluoro)pyridin-4-yl)-9 H -pyrrolo[2,3- b :4,5- c ']dipyridine ( 18 F-PI-2620). The in vivo diagnosis is currently established on clinical grounds and supported by midbrain atrophy estimation in structural MRI. Here, we investigate whether 18 F-PI-2620 tau PET has the potential to improve the imaging diagnosis of PSP. Methods: In this multicenter observational study, dynamic (0-60 min after injection) 18 F-PI-2620 PET and structural MRI data for 36 patients with PSP, 22 with PSP-Richardson syndrome, and 14 with a clinical phenotype other than Richardson syndrome (i.e., variant PSP) were analyzed along with data for 10 age-matched healthy controls (HCs). The PET data underwent kinetic modeling, which resulted in distribution volume ratio (DVR) images. These and the MR images were visually assessed by 3 masked experts for typical PSP signs. Furthermore, established midbrain atrophy parameters were measured in structural MR images, and regional DVRs were measured in typical tau-in-PSP target regions in the PET data. Results: Visual assessments discriminated PSP patients and HCs with an accuracy of 63% for MRI and 80% for the combination of MRI and 18 F-PI-2620 PET. As compared with patients of the PSP-Richardson syndrome subgroup, those of the variant PSP subgroup profited more in terms of sensitivity from the addition of the visual 18 F-PI-2620 PET to the visual MRI information (35% vs. 22%). In quantitative image evaluation, midbrain-to-pons area ratio and globus pallidus DVRs discriminated best between the PSP patients and HCs, with sensitivities and specificities of 83% and 90%, respectively, for MRI and 94% and 100%, respectively, for the combination of MRI and 18 F-PI-2620 PET. The gain of sensitivity by adding 18 F-PI-2620 PET to MRI data was more marked in clinically less affected patients than in more affected patients (37% vs. 19% for visual, and 16% vs. 12% for quantitative image evaluation). Conclusion: These results provide evidence for an improved imaging-based PSP diagnosis by adding 18 F-PI-2620 tau PET to structural MRI. This approach seems to be particularly promising at earlier disease stages and could be of value both for improving early clinical PSP diagnosis and for enriching PSP cohorts for trials of disease-modifying drugs., (© 2022 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2022

2. Tau PET imaging with 18 F-PI-2620 in Patients with Alzheimer Disease and Healthy Controls: A First-in-Humans Study.

Author

Mueller A, Bullich S, Barret O, Madonia J, Berndt M, Papin C, Perrotin A, Koglin N, Kroth H, Pfeifer A, Tamagnan G, Seibyl JP, Marek K, De Santi S, Dinkelborg LM, and Stephens AW

Subjects

Aged, Aged, 80 and over, Female, Humans, Male, Middle Aged, Alzheimer Disease diagnostic imaging, Fluorine Radioisotopes metabolism, Positron-Emission Tomography methods, Pyridines metabolism, Radiopharmaceuticals metabolism, tau Proteins metabolism

Abstract

18 F-PI-2620 is a PET tracer with high binding affinity for aggregated tau, a key pathologic feature of Alzheimer disease (AD) and other neurodegenerative disorders. Preclinically, 18 F-PI-2620 binds to both 3-repeat and 4-repeat tau isoforms. The purpose of this first-in-humans study was to evaluate the ability of 18 F-PI-2620 to detect tau pathology in AD patients using PET imaging, as well as to assess the safety and tolerability of this new tau PET tracer. Methods: Participants with a clinical diagnosis of probable AD and healthy controls (HCs) underwent dynamic 18 F-PI-2620 PET imaging for 180 min. 18 F-PI-2620 binding was assessed visually and quantitatively using distribution volume ratios (DVR) estimated from noninvasive tracer kinetics and SUV ratio (SUVR) measured at different time points after injection, with the cerebellar cortex as the reference region. Time-activity curves and SUVR were assessed in AD and HC subjects, as well as DVR and SUVR correlations and effect size (Cohen's d) over time. Results: 18 F-PI-2620 showed peak brain uptake around 5 min after injection and fast washout from nontarget regions. In AD subjects, focal asymmetric uptake was evident in temporal and parietal lobes, precuneus, and posterior cingulate cortex. DVR and SUVR in these regions were significantly higher in AD subjects than in HCs. Very low background signal was observed in HCs. 18 F-PI-2620 administration was safe and well tolerated. SUVR time-activity curves in most regions and subjects achieved a secular equilibrium after 40 min after injection. A strong correlation ( R 2 > 0.93) was found between noninvasive DVR and SUVR for all imaging windows starting at more than 30 min after injection. Similar effect sizes between AD and HC groups were obtained across the different imaging windows. 18 F-PI-2620 uptake in neocortical regions significantly correlated with the degree of cognitive impairment. Conclusion: Initial clinical data obtained in AD and HC subjects demonstrated a high image quality and excellent signal-to-noise ratio of 18 F-PI-2620 PET for imaging tau deposition in AD subjects. Noninvasive quantification using DVR and SUVR for 30-min imaging windows between 30 and 90 min after injection-for example, 45-75 min-provides robust and significant discrimination between AD and HC subjects. 18 F-PI-2620 uptake in expected regions correlates strongly with neurocognitive performance., (© 2020 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2020

3. Evaluation of Dosimetry, Quantitative Methods, and Test-Retest Variability of 18 F-PI-2620 PET for the Assessment of Tau Deposits in the Human Brain.

Author

Bullich S, Barret O, Constantinescu C, Sandiego C, Mueller A, Berndt M, Papin C, Perrotin A, Koglin N, Kroth H, Pfeifer A, Tamagnan G, Madonia J, Seibyl JP, Marek K, De Santi S, Dinkelborg LM, and Stephens AW

Subjects

Adult, Aged, Female, Humans, Male, Middle Aged, Models, Biological, Tissue Distribution, Alzheimer Disease diagnostic imaging, Brain metabolism, Fluorine Radioisotopes pharmacokinetics, Positron-Emission Tomography methods, Pyridines pharmacokinetics, Radiopharmaceuticals pharmacokinetics, tau Proteins metabolism

Abstract

18 F-PI-2620 is a next-generation tau PET tracer that has demonstrated ability to image the spatial distribution of suspected tau pathology. The objective of this study was to assess the tracer biodistribution, dosimetry, and quantitative methods of 18 F-PI-2620 in the human brain. Full kinetic modeling to quantify tau load was investigated. Noninvasive kinetic modeling and semiquantitative methods were evaluated against the full tracer kinetics. Finally, the reproducibility of PET measurements from test and retest scans was assessed. Methods: Three healthy controls (HCs) and 4 Alzheimer disease (AD) subjects underwent 2 dynamic PET scans, including arterial sampling. Distribution volume ratio (DVR) was estimated using full tracer kinetics (reversible 2-tissue-compartment [2TC] model and Logan graphical analysis [LGA]) and noninvasive kinetic models (noninvasive LGA [NI-LGA] and the multilinear reference tissue model [MRTM2]). SUV ratio (SUVR) was determined at different imaging windows after injection. The correlation between DVR and SUVR, effect size (Cohen's d), and test-retest variability (TRV) were evaluated. Additionally, 6 HCs received 1 tracer administration and underwent whole-body PET for dosimetry calculation. Organ doses and the whole-body effective dose were calculated using OLINDA 2.0. Results: A strong correlation was found across different kinetic models ( R 2 > 0.97) and between DVR(2TC) and SUVR between 30 and 90 min, with an R 2 of more than 0.95. Secular equilibrium was reached at around 40 min after injection in most regions and subjects. TRV and effect size for SUVR across different regions were similar at 30-60 min (TRV, 3.8%; Cohen's d, 3.80), 45-75 min (TRV, 4.3%; Cohen's d, 3.77) and 60-90 min (TRV, 4.9%; Cohen's d, 3.73) and increased at later time points. Elimination was via the hepatobiliary and urinary systems. The whole-body effective dose was 33.3 ± 2.1 μSv/MBq for an adult female and 33.1 ± 1.4 μSv/MBq for an adult male, with a 1.5-h urinary bladder voiding interval. Conclusion: 18 F-PI-2620 exhibits fast kinetics, suitable dosimetry, and low TRV. DVR measured using the 2TC model with arterial sampling correlated strongly with DVR measured by NI-LGA, MRTM2, and SUVR. SUVR can be used for 18 F-PI-2620 PET quantification of tau deposits, avoiding arterial blood sampling. Static 18 F-PI-2620 PET scans between 45 and 75 min after injection provide excellent quantification accuracy, a large effect size, and low TRV., (© 2020 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2020