Walk-through flat panel total-body PET : a patient-centered design for high throughput imaging at lower cost using DOI-capable high-resolution monolithic detectors
- Author
- Stefaan Vandenberghe (UGent) , Florence Marie Muller (UGent) , Nadia Withofs, Meysam Dadgar (UGent) , Jens Maebe (UGent) , Boris Vervenne (UGent) , Maya Abi Akl (UGent) , Song Xue, Kuangyu Shi, Giancarlo Sportelli, Nicola Belcari, Roland Hustinx, Christian Vanhove (UGent) and Joel S. Karp
- Organization
- Project
- Abstract
- Purpose Long axial field-of-view (LAFOV) systems have a much higher sensitivity than standard axial field-of-view (SAFOV) PET systems for imaging the torso or full body, which allows faster and/or lower dose imaging. Despite its very high sensitivity, current total-body PET (TB-PET) throughput is limited by patient handling (positioning on the bed) and often a shortage of available personnel. This factor, combined with high system costs, makes it hard to justify the implementation of these systems for many academic and nearly all routine nuclear medicine departments. We, therefore, propose a novel, cost-effective, dual flat panel TB-PET system for patients in upright standing positions to avoid the time-consuming positioning on a PET-CT table; the walk-through (WT) TB-PET. We describe a patient-centered, flat panel PET design that offers very efficient patient throughput and uses monolithic detectors (with BGO or LYSO) with depth-of-interaction (DOI) capabilities and high intrinsic spatial resolution. We compare system sensitivity, component costs, and patient throughput of the proposed WT-TB-PET to a SAFOV (= 26 cm) and a LAFOV (= 106 cm) LSO PET systems. Methods Patient width, height (= top head to start of thighs) and depth (= distance from the bed to front of patient) were derived from 40 randomly selected PET-CT scans to define the design dimensions of the WT-TB-PET. We compare this new PET system to the commercially available Siemens Biograph Vision 600 (SAFOV) and Siemens Quadra (LAFOV) PET-CT in terms of component costs, system sensitivity, and patient throughput. System cost comparison was based on estimating the cost of the two main components in the PET system (Silicon Photomultipliers (SiPMs) and scintillators). Sensitivity values were determined using Gate Monte Carlo simulations. Patient throughput times (including CT and scout scan, patient positioning on bed and transfer) were recorded for 1 day on a Siemens Vision 600 PET. These timing values were then used to estimate the expected patient throughput (assuming an equal patient radiotracer injected activity to patients and considering differences in system sensitivity and time-of-flight information) for WT-TB-PET, SAFOV and LAFOV PET. Results The WT-TB-PET is composed of two flat panels; each is 70 cm wide and 106 cm high, with a 50-cm gap between both panels. These design dimensions were justified by the patient sizes measured from the 40 random PET-CT scans. Each panel consists of 14 × 20 monolithic BGO detector blocks that are 50 × 50 × 16 mm in size and are coupled to a readout with 6 × 6 mm SiPMs arrays. For the WT-TB-PET, the detector surface is reduced by a factor of 1.9 and the scintillator volume by a factor of 2.2 compared to LAFOV PET systems, while demonstrating comparable sensitivity and much better uniform spatial resolution (< 2 mm in all directions over the FOV). The estimated component cost for the WT-TB-PET is 3.3 × lower than that of a 106 cm LAFOV system and only 20% higher than the PET component costs of a SAFOV. The estimated maximum number of patients scanned on a standard 8-h working day increases from 28 (for SAFOV) to 53–60 (for LAFOV in limited/full acceptance) to 87 (for the WT-TB-PET). By scanning faster (more patients), the amount of ordered activity per patient can be reduced drastically: the WT-TB-PET requires 66% less ordered activity per patient than a SAFOV. Conclusions We propose a monolithic BGO or LYSO-based WT-TB-PET system with DOI measurements that departs from the classical patient positioning on a table and allows patients to stand upright between two flat panels. The WT-TB-PET system provides a solution to achieve a much lower cost TB-PET approaching the cost of a SAFOV system. High patient throughput is increased by fast patient positioning between two vertical flat panel detectors of high sensitivity. High spatial resolution (< 2 mm) uniform over the FOV is obtained by using DOI-capable monolithic scintillators.
- Keywords
- Radiology, Nuclear Medicine and imaging, General Medicine, L(Y)SO, BGO, Walk-through PET, Cost-lifetime analysis, Patient throughput, Monolithic detector, Total-body PET, Positron emission tomography
Downloads
-
s00259-023-06341-x.pdf
- full text (Published version)
- |
- open access
- |
- |
- 1.11 MB
Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01H64137K038NZXYY4PEHVGN3W
- MLA
- Vandenberghe, Stefaan, et al. “Walk-through Flat Panel Total-Body PET : A Patient-Centered Design for High Throughput Imaging at Lower Cost Using DOI-Capable High-Resolution Monolithic Detectors.” EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING, vol. 50, no. 12, 2023, pp. 3558–71, doi:10.1007/s00259-023-06341-x.
- APA
- Vandenberghe, S., Muller, F. M., Withofs, N., Dadgar, M., Maebe, J., Vervenne, B., … Karp, J. S. (2023). Walk-through flat panel total-body PET : a patient-centered design for high throughput imaging at lower cost using DOI-capable high-resolution monolithic detectors. EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING, 50(12), 3558–3571. https://doi.org/10.1007/s00259-023-06341-x
- Chicago author-date
- Vandenberghe, Stefaan, Florence Marie Muller, Nadia Withofs, Meysam Dadgar, Jens Maebe, Boris Vervenne, Maya Abi Akl, et al. 2023. “Walk-through Flat Panel Total-Body PET : A Patient-Centered Design for High Throughput Imaging at Lower Cost Using DOI-Capable High-Resolution Monolithic Detectors.” EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING 50 (12): 3558–71. https://doi.org/10.1007/s00259-023-06341-x.
- Chicago author-date (all authors)
- Vandenberghe, Stefaan, Florence Marie Muller, Nadia Withofs, Meysam Dadgar, Jens Maebe, Boris Vervenne, Maya Abi Akl, Song Xue, Kuangyu Shi, Giancarlo Sportelli, Nicola Belcari, Roland Hustinx, Christian Vanhove, and Joel S. Karp. 2023. “Walk-through Flat Panel Total-Body PET : A Patient-Centered Design for High Throughput Imaging at Lower Cost Using DOI-Capable High-Resolution Monolithic Detectors.” EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING 50 (12): 3558–3571. doi:10.1007/s00259-023-06341-x.
- Vancouver
- 1.Vandenberghe S, Muller FM, Withofs N, Dadgar M, Maebe J, Vervenne B, et al. Walk-through flat panel total-body PET : a patient-centered design for high throughput imaging at lower cost using DOI-capable high-resolution monolithic detectors. EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING. 2023;50(12):3558–71.
- IEEE
- [1]S. Vandenberghe et al., “Walk-through flat panel total-body PET : a patient-centered design for high throughput imaging at lower cost using DOI-capable high-resolution monolithic detectors,” EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING, vol. 50, no. 12, pp. 3558–3571, 2023.
@article{01H64137K038NZXYY4PEHVGN3W, abstract = {{Purpose Long axial field-of-view (LAFOV) systems have a much higher sensitivity than standard axial field-of-view (SAFOV) PET systems for imaging the torso or full body, which allows faster and/or lower dose imaging. Despite its very high sensitivity, current total-body PET (TB-PET) throughput is limited by patient handling (positioning on the bed) and often a shortage of available personnel. This factor, combined with high system costs, makes it hard to justify the implementation of these systems for many academic and nearly all routine nuclear medicine departments. We, therefore, propose a novel, cost-effective, dual flat panel TB-PET system for patients in upright standing positions to avoid the time-consuming positioning on a PET-CT table; the walk-through (WT) TB-PET. We describe a patient-centered, flat panel PET design that offers very efficient patient throughput and uses monolithic detectors (with BGO or LYSO) with depth-of-interaction (DOI) capabilities and high intrinsic spatial resolution. We compare system sensitivity, component costs, and patient throughput of the proposed WT-TB-PET to a SAFOV (= 26 cm) and a LAFOV (= 106 cm) LSO PET systems. Methods Patient width, height (= top head to start of thighs) and depth (= distance from the bed to front of patient) were derived from 40 randomly selected PET-CT scans to define the design dimensions of the WT-TB-PET. We compare this new PET system to the commercially available Siemens Biograph Vision 600 (SAFOV) and Siemens Quadra (LAFOV) PET-CT in terms of component costs, system sensitivity, and patient throughput. System cost comparison was based on estimating the cost of the two main components in the PET system (Silicon Photomultipliers (SiPMs) and scintillators). Sensitivity values were determined using Gate Monte Carlo simulations. Patient throughput times (including CT and scout scan, patient positioning on bed and transfer) were recorded for 1 day on a Siemens Vision 600 PET. These timing values were then used to estimate the expected patient throughput (assuming an equal patient radiotracer injected activity to patients and considering differences in system sensitivity and time-of-flight information) for WT-TB-PET, SAFOV and LAFOV PET. Results The WT-TB-PET is composed of two flat panels; each is 70 cm wide and 106 cm high, with a 50-cm gap between both panels. These design dimensions were justified by the patient sizes measured from the 40 random PET-CT scans. Each panel consists of 14 × 20 monolithic BGO detector blocks that are 50 × 50 × 16 mm in size and are coupled to a readout with 6 × 6 mm SiPMs arrays. For the WT-TB-PET, the detector surface is reduced by a factor of 1.9 and the scintillator volume by a factor of 2.2 compared to LAFOV PET systems, while demonstrating comparable sensitivity and much better uniform spatial resolution (< 2 mm in all directions over the FOV). The estimated component cost for the WT-TB-PET is 3.3 × lower than that of a 106 cm LAFOV system and only 20% higher than the PET component costs of a SAFOV. The estimated maximum number of patients scanned on a standard 8-h working day increases from 28 (for SAFOV) to 53–60 (for LAFOV in limited/full acceptance) to 87 (for the WT-TB-PET). By scanning faster (more patients), the amount of ordered activity per patient can be reduced drastically: the WT-TB-PET requires 66% less ordered activity per patient than a SAFOV. Conclusions We propose a monolithic BGO or LYSO-based WT-TB-PET system with DOI measurements that departs from the classical patient positioning on a table and allows patients to stand upright between two flat panels. The WT-TB-PET system provides a solution to achieve a much lower cost TB-PET approaching the cost of a SAFOV system. High patient throughput is increased by fast patient positioning between two vertical flat panel detectors of high sensitivity. High spatial resolution (< 2 mm) uniform over the FOV is obtained by using DOI-capable monolithic scintillators.}}, author = {{Vandenberghe, Stefaan and Muller, Florence Marie and Withofs, Nadia and Dadgar, Meysam and Maebe, Jens and Vervenne, Boris and Abi Akl, Maya and Xue, Song and Shi, Kuangyu and Sportelli, Giancarlo and Belcari, Nicola and Hustinx, Roland and Vanhove, Christian and Karp, Joel S.}}, issn = {{1619-7070}}, journal = {{EUROPEAN JOURNAL OF NUCLEAR MEDICINE AND MOLECULAR IMAGING}}, keywords = {{Radiology, Nuclear Medicine and imaging,General Medicine,L(Y)SO,BGO,Walk-through PET,Cost-lifetime analysis,Patient throughput,Monolithic detector,Total-body PET,Positron emission tomography}}, language = {{eng}}, number = {{12}}, pages = {{3558--3571}}, title = {{Walk-through flat panel total-body PET : a patient-centered design for high throughput imaging at lower cost using DOI-capable high-resolution monolithic detectors}}, url = {{http://doi.org/10.1007/s00259-023-06341-x}}, volume = {{50}}, year = {{2023}}, }
- Altmetric
- View in Altmetric
- Web of Science
- Times cited: