Feasibility of positron range correction in 82-Rubidium cardiac PET/CT

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Standard

Feasibility of positron range correction in 82-Rubidium cardiac PET/CT. / Jensen, Malte; Bentsen, Simon; Clemmensen, Andreas; Jensen, Jacob Kildevang; Madsen, Johanne; Rossing, Jonas; Laier, Anna; Hasbak, Philip; Kjaer, Andreas; Ripa, Rasmus Sejersten.

I: EJNMMI Physics, Bind 9, Nr. 1, 51, 2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Jensen, M, Bentsen, S, Clemmensen, A, Jensen, JK, Madsen, J, Rossing, J, Laier, A, Hasbak, P, Kjaer, A & Ripa, RS 2022, 'Feasibility of positron range correction in 82-Rubidium cardiac PET/CT', EJNMMI Physics, bind 9, nr. 1, 51. https://doi.org/10.1186/s40658-022-00480-0

APA

Jensen, M., Bentsen, S., Clemmensen, A., Jensen, J. K., Madsen, J., Rossing, J., Laier, A., Hasbak, P., Kjaer, A., & Ripa, R. S. (2022). Feasibility of positron range correction in 82-Rubidium cardiac PET/CT. EJNMMI Physics, 9(1), [51]. https://doi.org/10.1186/s40658-022-00480-0

Vancouver

Jensen M, Bentsen S, Clemmensen A, Jensen JK, Madsen J, Rossing J o.a. Feasibility of positron range correction in 82-Rubidium cardiac PET/CT. EJNMMI Physics. 2022;9(1). 51. https://doi.org/10.1186/s40658-022-00480-0

Author

Jensen, Malte ; Bentsen, Simon ; Clemmensen, Andreas ; Jensen, Jacob Kildevang ; Madsen, Johanne ; Rossing, Jonas ; Laier, Anna ; Hasbak, Philip ; Kjaer, Andreas ; Ripa, Rasmus Sejersten. / Feasibility of positron range correction in 82-Rubidium cardiac PET/CT. I: EJNMMI Physics. 2022 ; Bind 9, Nr. 1.

Bibtex

@article{187754718d1041238a589657e1ceb5eb,
title = "Feasibility of positron range correction in 82-Rubidium cardiac PET/CT",
abstract = "Background Myocardial perfusion imaging (MPI) using positron emission tomography (PET) tracers is an essential tool in investigating diseases and treatment responses in cardiology. (82)Rubidium (Rb-82)-PET imaging is advantageous for MPI due to its short half-life, but cannot be used for small animal research due to the long positron range. We aimed to correct for this, enabling MPI with Rb-82-PET in rats. Methods The effect of positron range correction (PRC) on Rb-82-PET was examined using two phantoms and in vivo on rats. A NEMA NU-4-inspired phantom was used for image quality evaluation (%standard deviation (%SD), spillover ratio (SOR) and recovery coefficient (RC)). A cardiac phantom was used for assessing spatial resolution. Two rats underwent rest Rb-82-PET to optimize number of iterations, type of PRC and respiratory gating. Results NEMA NU-4 metrics (no PRC vs PRC): %SD 0.087 versus 0.103; SOR (air) 0.022 versus 0.002, SOR (water) 0.059 versus 0.019; RC (3 mm) 0.219 versus 0.584, RC (4 mm) 0.300 versus 0.874, RC (5 mm) 0.357 versus 1.197. Cardiac phantom full width at half maximum (FWHM) and full width at tenth maximum (FWTM) (no PRC vs. PRC): FWTM 6.73 mm versus 3.26 mm (true: 3 mm), FWTM 9.27 mm versus 7.01 mm. The in vivo scans with respiratory gating had a homogeneous myocardium clearly distinguishable from the blood pool. Conclusion PRC improved the spatial resolution for the phantoms and in vivo at the expense of slightly more noise. Combined with respiratory gating, the spatial resolution achieved using PRC should allow for quantitative MPI in small animals.",
keywords = "PET, MPI, Molecular imaging, Image reconstruction",
author = "Malte Jensen and Simon Bentsen and Andreas Clemmensen and Jensen, {Jacob Kildevang} and Johanne Madsen and Jonas Rossing and Anna Laier and Philip Hasbak and Andreas Kjaer and Ripa, {Rasmus Sejersten}",
year = "2022",
doi = "10.1186/s40658-022-00480-0",
language = "English",
volume = "9",
journal = "E J N M M I Physics",
issn = "2197-7364",
publisher = "SpringerOpen",
number = "1",

}

RIS

TY - JOUR

T1 - Feasibility of positron range correction in 82-Rubidium cardiac PET/CT

AU - Jensen, Malte

AU - Bentsen, Simon

AU - Clemmensen, Andreas

AU - Jensen, Jacob Kildevang

AU - Madsen, Johanne

AU - Rossing, Jonas

AU - Laier, Anna

AU - Hasbak, Philip

AU - Kjaer, Andreas

AU - Ripa, Rasmus Sejersten

PY - 2022

Y1 - 2022

N2 - Background Myocardial perfusion imaging (MPI) using positron emission tomography (PET) tracers is an essential tool in investigating diseases and treatment responses in cardiology. (82)Rubidium (Rb-82)-PET imaging is advantageous for MPI due to its short half-life, but cannot be used for small animal research due to the long positron range. We aimed to correct for this, enabling MPI with Rb-82-PET in rats. Methods The effect of positron range correction (PRC) on Rb-82-PET was examined using two phantoms and in vivo on rats. A NEMA NU-4-inspired phantom was used for image quality evaluation (%standard deviation (%SD), spillover ratio (SOR) and recovery coefficient (RC)). A cardiac phantom was used for assessing spatial resolution. Two rats underwent rest Rb-82-PET to optimize number of iterations, type of PRC and respiratory gating. Results NEMA NU-4 metrics (no PRC vs PRC): %SD 0.087 versus 0.103; SOR (air) 0.022 versus 0.002, SOR (water) 0.059 versus 0.019; RC (3 mm) 0.219 versus 0.584, RC (4 mm) 0.300 versus 0.874, RC (5 mm) 0.357 versus 1.197. Cardiac phantom full width at half maximum (FWHM) and full width at tenth maximum (FWTM) (no PRC vs. PRC): FWTM 6.73 mm versus 3.26 mm (true: 3 mm), FWTM 9.27 mm versus 7.01 mm. The in vivo scans with respiratory gating had a homogeneous myocardium clearly distinguishable from the blood pool. Conclusion PRC improved the spatial resolution for the phantoms and in vivo at the expense of slightly more noise. Combined with respiratory gating, the spatial resolution achieved using PRC should allow for quantitative MPI in small animals.

AB - Background Myocardial perfusion imaging (MPI) using positron emission tomography (PET) tracers is an essential tool in investigating diseases and treatment responses in cardiology. (82)Rubidium (Rb-82)-PET imaging is advantageous for MPI due to its short half-life, but cannot be used for small animal research due to the long positron range. We aimed to correct for this, enabling MPI with Rb-82-PET in rats. Methods The effect of positron range correction (PRC) on Rb-82-PET was examined using two phantoms and in vivo on rats. A NEMA NU-4-inspired phantom was used for image quality evaluation (%standard deviation (%SD), spillover ratio (SOR) and recovery coefficient (RC)). A cardiac phantom was used for assessing spatial resolution. Two rats underwent rest Rb-82-PET to optimize number of iterations, type of PRC and respiratory gating. Results NEMA NU-4 metrics (no PRC vs PRC): %SD 0.087 versus 0.103; SOR (air) 0.022 versus 0.002, SOR (water) 0.059 versus 0.019; RC (3 mm) 0.219 versus 0.584, RC (4 mm) 0.300 versus 0.874, RC (5 mm) 0.357 versus 1.197. Cardiac phantom full width at half maximum (FWHM) and full width at tenth maximum (FWTM) (no PRC vs. PRC): FWTM 6.73 mm versus 3.26 mm (true: 3 mm), FWTM 9.27 mm versus 7.01 mm. The in vivo scans with respiratory gating had a homogeneous myocardium clearly distinguishable from the blood pool. Conclusion PRC improved the spatial resolution for the phantoms and in vivo at the expense of slightly more noise. Combined with respiratory gating, the spatial resolution achieved using PRC should allow for quantitative MPI in small animals.

KW - PET

KW - MPI

KW - Molecular imaging

KW - Image reconstruction

U2 - 10.1186/s40658-022-00480-0

DO - 10.1186/s40658-022-00480-0

M3 - Journal article

C2 - 35907082

VL - 9

JO - E J N M M I Physics

JF - E J N M M I Physics

SN - 2197-7364

IS - 1

M1 - 51

ER -

ID: 316685698