Online proton therapy monitoring: clinical test of a Silicon-photodetector-based in-beam PET

Ferrero, Veronica; Fiorina, Elisa; Morrocchi, M.; Pennazio, Francesco; Baroni, Guido; Battistoni, G.; Belcari, Nicola; Camarlinghi, N.; Ciocca, Mario; Guerra, Alberto Del; Donetti, M.; Giordanengo, S.; Giraudo, G.; Patera, V.; Peroni, C.; Rivetti, A.; Rolo, M.; Rossi, S.; Rosso, V.; Sportelli, Giancarlo; Tampellini, S.; Valvo, Francesca; Wheadon, R.; Cerello, Piergiorgio; Bisogni, Maria Giuseppina

doi:10.1038/s41598-018-22325-6

Cited by 115 publications

(112 citation statements)

References 28 publications

(34 reference statements)

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“…Positron emitters are generated inside the patient during treatment, and therefore, by using PET imaging the delivered dose can be indirectly measured [338,339]. This can be done during the irradiation (on-line or in-beam PET), which is beneficial when imaging short-lived emitters [340], or after the treatment in an off-site system (off-line), which can provide better counting statistics for relatively long-lived radionuclides [341]. In on-line systems, the integration of PET imaging into the treatment environment poses geometric constraints, conditioning the imaging performance.…”

Section: Dual-modality Tracers/contrastsmentioning

confidence: 99%

Hybrid Imaging: Instrumentation and Data Processing

et al. 2018

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State-of-the-art patient management frequently requires the use of non-invasive imaging methods to assess the anatomy, function or molecular-biological conditions of patients or study subjects. Such imaging methods can be singular, providing either anatomical or molecular information, or they can be combined, thus, providing "anato-metabolic" information. Hybrid imaging denotes image acquisitions on systems that physically combine complementary imaging modalities for an improved diagnostic accuracy and confidence as well as for increased patient comfort. The physical combination of formerly independent imaging modalities was driven by leading innovators in the field of clinical research and benefited from technological advances that permitted the operation of PET and MR in close physical proximity, for example. This review covers milestones of the development of various hybrid imaging systems for use in clinical practice and small-animal research. Special attention is given to technological advances that helped the adoption of hybrid imaging, as well as to introducing methodological concepts that benefit from the availability of complementary anatomical and biological information, such as new types of image reconstruction and data correction schemes. The ultimate goal of hybrid imaging is to provide useful, complementary and quantitative information during patient work-up. Hybrid imaging also opens the door to multi-parametric assessment of diseases, which will help us better understand the causes of various diseases that currently contribute to a large fraction of healthcare costs.

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Section: Dual-modality Tracers/contrastsmentioning

confidence: 99%

Hybrid Imaging: Instrumentation and Data Processing

et al. 2018

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“…Tracking of prompt-gamma, PET-gamma, and secondary protons and neutrons are examples [9][10][11]. Prototype systems for prompt-gamma and PET-gamma range monitoring were tested clinically and obtained satisfying precision of Bragg peak position monitoring on-line in the PBT treatment room [12][13][14]. At the Jagiellonian University in Kraków, a novel solution for diagnostic PET imaging, Jagiellonian-PET (J-PET) is being developed [15][16][17][18].…”

Section: J-pet Detector To Address Physical Range Uncertainties Of Prmentioning

confidence: 99%

Characterisation of Components of a Scintillation-fiber-based Compton Camera

Wrońska¹,

Hetzel²,

Kasper³

et al. 2020

Acta Phys. Pol. B

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Physical and biological range uncertainties limit the clinical potential of Proton Beam Therapy (PBT). In these proceedings, we report on two research projects, which we are conducting in parallel and which both tackle the problem of range uncertainties. One aims at developing software tools and the other at developing detector instrumentation. Regarding the first, we report on our development and pre-clinical application of a GPU-accelerated Monte Carlo (MC) simulation toolkit Fred. Concerning the letter, we report on our investigations of plastic-scintillator-based PET detectors for particle therapy delivery monitoring. We study the feasibility of Jagiellonian-PET detector technology for proton beam therapy range monitoring by means of MC simulations of the β + activity induced in a phantom-by-proton beams and present preliminary results of PET image reconstruction. Using a GPU-accelerated Monte Carlo simulation toolkit Fred and plastic-scintillator-based PET detectors, we aim at improving the patient treatment quality with protons.

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“…Tracking of prompt-gamma, PET-gamma and secondary protons and neutrons are examples [9,10,11]. Prototype systems for prompt-gamma and PET-gamma range monitoring were tested clinically and obtained satisfying precision of Bragg-peak position monitoring on-line in the PBT treatment room [12,13,14]. At the Jagiellonian University in Kraków, a novel solution for diagnostic PET imaging, Jagiellonian-PET (J-PET) is being developed.…”

Section: J-pet Detector To Address Physical Range Uncertainties Of Prmentioning

confidence: 99%

Investigations on Physical and Biological Range Uncertainties in Krak\'ow Proton Beam Therapy Centre

Ruciński¹,

Baran²,

Battistoni³

et al. 2020

Acta Phys. Pol. B

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Physical and biological range uncertainties limit the clinical potential of Proton Beam Therapy (PBT). In this proceedings, we report on two research projects, which we are conducting in parallel and which both tackle the problem of range uncertainties. One aims at developing software tools and the other at developing detector instrumentation. Regarding the first, we report on our development and pre-clinical application of a GPUaccelerated Monte Carlo (MC) simulation toolkit Fred. Concerning the letter, we report on our investigations of plastic scintillator based PET detectors for particle therapy delivery monitoring. We study the feasibility of Jagiellonian-PET detector technology for proton beam therapy range monitoring by means of MC simulations of the β + activity induced in a phantom by proton beams and present preliminary results of PET image reconstruction. Using a GPU-accelerated Monte Carlo simulation toolkit Fred and plastic scintillator based PET detectors we aim to improve patient treatment quality with protons.

show abstract

Online proton therapy monitoring: clinical test of a Silicon-photodetector-based in-beam PET

Cited by 115 publications

References 28 publications

Hybrid Imaging: Instrumentation and Data Processing

Hybrid Imaging: Instrumentation and Data Processing

Characterisation of Components of a Scintillation-fiber-based Compton Camera

Investigations on Physical and Biological Range Uncertainties in Krak\'ow Proton Beam Therapy Centre

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