Protontherapy is an important radiation modality that has been used to treat cancer for over 60 years. In the last 10 years, clinical proton therapy has been rapidly growing with more than 80 facilities worldwide [1]. The interest in proton therapy stems from the physical properties of protons allowing for a much improved dose shaping around the target and greater healthy tissue sparing. One shortcoming of protontherapy is its inability to treat radioresistant cancers, being protons radiobiologically almost as effective as photons. Heavier particles, such as 12C ions, can overcome radioresistance but they present radiobiological and economic issues that hamper their widespread adoption. Therefore, many strategies have been designed to increase the biological effectiveness of proton beams. Examples are chemical radiosensitizing agents or, more recently, metallic nanoparticles. The goal of this project is to investigate the use of nuclear reactions triggered by protons generating short-range high- LET alpha particles inside the tumours, thereby allowing a highly localized DNA-damaging action. Specifically, we intend to consolidate and explain the promising results recently published in [2], where a significant enhancement of biological effectiveness was achieved by the p-11B reaction. Clinically relevant binary approaches were first proposed with Boron Neutron Capture Therapy (BNCT), which exploits thermal neutron capture in 10B, suitably accumulated into tumour before irradiation. The radiosensitising effects due to the presence of 10B will be compared to those elicited by p-11B, using the same carrier and relating the observed effects with intracellular 11B and 10B distribution as well as modelled particle action and measured dose deposition at the micro/nanometer scale. Moreover, the p-19F reaction, which also generates secondary particles potentially leading to local enhancement of proton effectiveness, will be investigated. The in-vivo imaging of 11B and 19F carriers will be studied, in particular by optimizing 19F-based magnetic resonance.
NEPTUNE (Nuclear process-driven Enhancement of Proton Therapy UNravEled) / Manti, Lorenzo; Blaha, Pavel; Ricciardi, Valerio; Feoli, Chiara; Quarto, Maria. - (2019).
NEPTUNE (Nuclear process-driven Enhancement of Proton Therapy UNravEled)
Lorenzo MantiFunding Acquisition
;Pavel Blaha;Chiara Feoli;Maria Quarto
2019
Abstract
Protontherapy is an important radiation modality that has been used to treat cancer for over 60 years. In the last 10 years, clinical proton therapy has been rapidly growing with more than 80 facilities worldwide [1]. The interest in proton therapy stems from the physical properties of protons allowing for a much improved dose shaping around the target and greater healthy tissue sparing. One shortcoming of protontherapy is its inability to treat radioresistant cancers, being protons radiobiologically almost as effective as photons. Heavier particles, such as 12C ions, can overcome radioresistance but they present radiobiological and economic issues that hamper their widespread adoption. Therefore, many strategies have been designed to increase the biological effectiveness of proton beams. Examples are chemical radiosensitizing agents or, more recently, metallic nanoparticles. The goal of this project is to investigate the use of nuclear reactions triggered by protons generating short-range high- LET alpha particles inside the tumours, thereby allowing a highly localized DNA-damaging action. Specifically, we intend to consolidate and explain the promising results recently published in [2], where a significant enhancement of biological effectiveness was achieved by the p-11B reaction. Clinically relevant binary approaches were first proposed with Boron Neutron Capture Therapy (BNCT), which exploits thermal neutron capture in 10B, suitably accumulated into tumour before irradiation. The radiosensitising effects due to the presence of 10B will be compared to those elicited by p-11B, using the same carrier and relating the observed effects with intracellular 11B and 10B distribution as well as modelled particle action and measured dose deposition at the micro/nanometer scale. Moreover, the p-19F reaction, which also generates secondary particles potentially leading to local enhancement of proton effectiveness, will be investigated. The in-vivo imaging of 11B and 19F carriers will be studied, in particular by optimizing 19F-based magnetic resonance.File | Dimensione | Formato | |
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