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NEMA NU 2–2007 performance characteristics of GE Signa integrated PET/MR for different PET isotopes

BACKGROUND: Fully integrated PET/MR systems are being used frequently in clinical research and routine. National Electrical Manufacturers Association (NEMA) characterization of these systems is generally done with (18)F which is clinically the most relevant PET isotope. However, other PET isotopes,...

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Detalles Bibliográficos
Autores principales: Caribé, Paulo R. R. V., Koole, M., D’Asseler, Yves, Deller, Timothy W., Van Laere, K., Vandenberghe, S.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Springer International Publishing 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6609673/
https://www.ncbi.nlm.nih.gov/pubmed/31273558
http://dx.doi.org/10.1186/s40658-019-0247-x
Descripción
Sumario:BACKGROUND: Fully integrated PET/MR systems are being used frequently in clinical research and routine. National Electrical Manufacturers Association (NEMA) characterization of these systems is generally done with (18)F which is clinically the most relevant PET isotope. However, other PET isotopes, such as (68)Ga and (90)Y, are gaining clinical importance as they are of specific interest for oncological applications and for follow-up of (90)Y-based radionuclide therapy. These isotopes have a complex decay scheme with a variety of prompt gammas in coincidence. (68)Ga and (90)Y have higher positron energy and, because of the larger positron range, there may be interference with the magnetic field of the MR compared to (18)F. Therefore, it is relevant to determine the performance of PET/MR for these clinically relevant and commercially available isotopes. METHODS: NEMA NU 2–2007 performance measurements were performed for characterizing the spatial resolution, sensitivity, image quality, and the accuracy of attenuation and scatter corrections for (18)F, (68)Ga, and (90)Y. Scatter fraction and noise equivalent count rate (NECR) tests were performed using (18)F and (68)Ga. All phantom data were acquired on the GE Signa integrated PET/MR system, installed in UZ Leuven, Belgium. RESULTS: (18)F, (68)Ga, and (90)Y NEMA performance tests resulted in substantially different system characteristics. In comparison with (18)F, the spatial resolution is about 1 mm larger in the axial direction for (68)Ga and no significative effect was found for (90)Y. The impact of this lower resolution is also visible in the recovery coefficients of the smallest spheres of (68)Ga in image quality measurements, where clearly lower values are obtained. For (90)Y, the low number of counts leads to a large variability in the image quality measurements. The primary factor for the sensitivity change is the scale factor related to the positron emission fraction. There is also an impact on the peak NECR, which is lower for (68)Ga than for (18)F and appears at higher activities. CONCLUSIONS: The system performance of GE Signa integrated PET/MR was substantially different, in terms of NEMA spatial resolution, image quality, and NECR for (68)Ga and (90)Y compared to (18)F. But these differences are compensated by the PET/MR scanner technologies and reconstructions methods.