Saved in:
Bibliographic Details
Main Authors: Gonzalez, Antonio J., Anreus-Valero, Alvaro, Sanchez, David, Jiménez-Serrano, Santiago, Freire, Marta, Gonzalez-Montoro, Andrea, Ulin-Briseno, Edwing Y., Cucarella, Neus, Barrio, John, Laing, Andrew, Álamo, Jorge, Barbera, Julio, Vidal, Luis F., Gil, Marc, Benlloch, Jose M., Rios, Alfonso, Bonmati, Luis Marti, Torres-Espallardo, Irene
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.09898
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917330192171008
author Gonzalez, Antonio J.
Anreus-Valero, Alvaro
Sanchez, David
Jiménez-Serrano, Santiago
Freire, Marta
Gonzalez-Montoro, Andrea
Ulin-Briseno, Edwing Y.
Cucarella, Neus
Barrio, John
Laing, Andrew
Álamo, Jorge
Barbera, Julio
Vidal, Luis F.
Gil, Marc
Benlloch, Jose M.
Rios, Alfonso
Bonmati, Luis Marti
Torres-Espallardo, Irene
author_facet Gonzalez, Antonio J.
Anreus-Valero, Alvaro
Sanchez, David
Jiménez-Serrano, Santiago
Freire, Marta
Gonzalez-Montoro, Andrea
Ulin-Briseno, Edwing Y.
Cucarella, Neus
Barrio, John
Laing, Andrew
Álamo, Jorge
Barbera, Julio
Vidal, Luis F.
Gil, Marc
Benlloch, Jose M.
Rios, Alfonso
Bonmati, Luis Marti
Torres-Espallardo, Irene
contents This work summarizes the design, construction, initial performance evaluation and pilot clinical results of the IMAS system, a long axial field of view (FOV), also known as total-body (TB-), positron emission tomography (PET) prototype scanner. This PET enables for the first time in TB-PET imaging, simultaneously time-of-flight (TOF) and depth-of-interaction (DOI) capabilities. The IMAS detector block is based on LYSO semi monolithic scintillators, with individual slab sizes of 3 mm x 25 mm x 20 mm each. Arrays of 1x8 slabs are coupled to 8x8 Silicon Photomultiplier arrays. A proprietary readout reduces the 64 signals to only 16 outputs, preserving both 3D photon impact positioning and timing accuracy. IMAS has a total of 30,720 channels. PETsys electronics is used for data acquisition. The IMAS geometry is based on 5 rings of 10 cm each, with a 5 cm gap between them. It defines an axial FOV of 71 cm with a bore aperture of 82 cm. We report in this work the pilot tests of the system performance and the first clinical results. We found that the system spatial resolution remained below 4 mm across the entire FOV, even at the off-radial position of 30 cm. A coincidence time resolution with a small size 22Na source of 560 ps FWHM was measured. A sensitivity of 56.54 cps/kBq is in good agreement with previous simulation studies; however, the noise equivalent count rates performance (79 kcps at 3.26 kBq/mL) was significantly lower than expected, likely due to a data transfer bottleneck between the system and the acquisition workstation. Finally, a comparison of one of the imaged patients with a commercial TOF PET/CT scanner is also provided, pinpointing an improved tumor identification for IMAS, and the advantages of TOF and especially DOI capabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2603_09898
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Initial Performance of a Long Axial FOV PET with TOF and DOI capabilities: IMAS system
Gonzalez, Antonio J.
Anreus-Valero, Alvaro
Sanchez, David
Jiménez-Serrano, Santiago
Freire, Marta
Gonzalez-Montoro, Andrea
Ulin-Briseno, Edwing Y.
Cucarella, Neus
Barrio, John
Laing, Andrew
Álamo, Jorge
Barbera, Julio
Vidal, Luis F.
Gil, Marc
Benlloch, Jose M.
Rios, Alfonso
Bonmati, Luis Marti
Torres-Espallardo, Irene
Medical Physics
This work summarizes the design, construction, initial performance evaluation and pilot clinical results of the IMAS system, a long axial field of view (FOV), also known as total-body (TB-), positron emission tomography (PET) prototype scanner. This PET enables for the first time in TB-PET imaging, simultaneously time-of-flight (TOF) and depth-of-interaction (DOI) capabilities. The IMAS detector block is based on LYSO semi monolithic scintillators, with individual slab sizes of 3 mm x 25 mm x 20 mm each. Arrays of 1x8 slabs are coupled to 8x8 Silicon Photomultiplier arrays. A proprietary readout reduces the 64 signals to only 16 outputs, preserving both 3D photon impact positioning and timing accuracy. IMAS has a total of 30,720 channels. PETsys electronics is used for data acquisition. The IMAS geometry is based on 5 rings of 10 cm each, with a 5 cm gap between them. It defines an axial FOV of 71 cm with a bore aperture of 82 cm. We report in this work the pilot tests of the system performance and the first clinical results. We found that the system spatial resolution remained below 4 mm across the entire FOV, even at the off-radial position of 30 cm. A coincidence time resolution with a small size 22Na source of 560 ps FWHM was measured. A sensitivity of 56.54 cps/kBq is in good agreement with previous simulation studies; however, the noise equivalent count rates performance (79 kcps at 3.26 kBq/mL) was significantly lower than expected, likely due to a data transfer bottleneck between the system and the acquisition workstation. Finally, a comparison of one of the imaged patients with a commercial TOF PET/CT scanner is also provided, pinpointing an improved tumor identification for IMAS, and the advantages of TOF and especially DOI capabilities.
title Initial Performance of a Long Axial FOV PET with TOF and DOI capabilities: IMAS system
topic Medical Physics
url https://arxiv.org/abs/2603.09898