Your search keyword '"Piersanti, L."' showing total 10 results

1. Secondary radiation measurements for particle therapy applications: prompt photons produced by4He,12C and16O ion beams in a PMMA target

Author

Mattei, I, primary, Bini, F, additional, Collamati, F, additional, De Lucia, E, additional, Frallicciardi, P M, additional, Iarocci, E, additional, Mancini-Terracciano, C, additional, Marafini, M, additional, Muraro, S, additional, Paramatti, R, additional, Patera, V, additional, Piersanti, L, additional, Pinci, D, additional, Rucinski, A, additional, Russomando, A, additional, Sarti, A, additional, Sciubba, A, additional, Solfaroli Camillocci, E, additional, Toppi, M, additional, Traini, G, additional, Voena, C, additional, and Battistoni, G, additional

Published

2017

2. Secondary radiation measurements for particle therapy applications: nuclear fragmentation produced by4He ion beams in a PMMA target

Author

Marafini, M, primary, Paramatti, R, additional, Pinci, D, additional, Battistoni, G, additional, Collamati, F, additional, De Lucia, E, additional, Faccini, R, additional, Frallicciardi, P M, additional, Mancini-Terracciano, C, additional, Mattei, I, additional, Muraro, S, additional, Piersanti, L, additional, Rovituso, M, additional, Rucinski, A, additional, Russomando, A, additional, Sarti, A, additional, Sciubba, A, additional, Solfaroli Camillocci, E, additional, Toppi, M, additional, Traini, G, additional, Voena, C, additional, and Patera, V, additional

Published

2017

3. Corrigendum: Charged particles flux measurement from PMMA irradiated by 80 MeV u−1carbon ion beam (Phys. Med. Biol.57 5667)

Author

Agodi, C, primary, Battistoni, G, additional, Bellini, F, additional, Cirrone, G A P, additional, Collamati, F, additional, Cuttone, G, additional, De Lucia, E, additional, De Napoli, M, additional, Di Domenico, A, additional, Faccini, R, additional, Ferroni, F, additional, Fiore, S, additional, Gauzzi, P, additional, Iarocci, E, additional, Marafini, M, additional, Mattei, I, additional, Muraro, S, additional, Paoloni, A, additional, Patera, V, additional, Piersanti, L, additional, Romano, F, additional, Sarti, A, additional, Sciubba, A, additional, Vitale, E, additional, and Voena, C, additional

Published

2014

4. Measurement of charged particle yields from PMMA irradiated by a 220 MeV/u12Cbeam

Author

Piersanti, L, primary, Bellini, F, additional, Bini, F, additional, Collamati, F, additional, De Lucia, E, additional, Durante, M, additional, Faccini, R, additional, Ferroni, F, additional, Fiore, S, additional, Iarocci, E, additional, Tessa, C La, additional, Marafini, M, additional, Mattei, I, additional, Patera, V, additional, Ortega, P G, additional, Sarti, A, additional, Schuy, C, additional, Sciubba, A, additional, Vanstalle, M, additional, and Voena, C, additional

Published

2014

5. Charged particle’s flux measurement from PMMA irradiated by 80 MeV/u carbon ion beam

Author

Agodi, C, primary, Battistoni, G, additional, Bellini, F, additional, Cirrone, G A P, additional, Collamati, F, additional, Cuttone, G, additional, De Lucia, E, additional, De Napoli, M, additional, Domenico, A Di, additional, Faccini, R, additional, Ferroni, F, additional, Fiore, S, additional, Gauzzi, P, additional, Iarocci, E, additional, Marafini, M, additional, Mattei, I, additional, Muraro, S, additional, Paoloni, A, additional, Patera, V, additional, Piersanti, L, additional, Romano, F, additional, Sarti, A, additional, Sciubba, A, additional, Vitale, E, additional, and Voena, C, additional

Published

2012

6. Measurement of charged particle yields from PMMA irradiated by a 220 MeV/u12Cbeam

Author

Fabiano Bini, S. Fiore, E. De Lucia, Michela Marafini, Pablo G. Ortega, Christoph Schuy, Luca Piersanti, Francesco Collamati, Alessio Sarti, C. La Tessa, F. Bellini, E. Iarocci, F. Ferroni, C. Voena, Marco Durante, Ilaria Mattei, M. Vanstalle, R. Faccini, Vincenzo Patera, A. Sciubba, Institut Pluridisciplinaire Hubert Curien (IPHC), Université de Strasbourg (UNISTRA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Piersanti, L., Bellini, F., Bini, F., Collamati, F., De Lucia, E., Durante, M., Faccini, R., Ferroni, F., Fiore, S., Iarocci, E., La Tessa, C., Marafini, M., Mattei, I., Patera, V., Ortega, P. G., Sarti, A., Schuy, C., Sciubba, A., Vanstalle, M., and Voena, C.

Subjects

medicine.medical_treatment, Physics::Medical Physics, LYSO, Dose profile, Bragg peak, 01 natural sciences, Particle detector, Lyso, Particle identification, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, hadrontherapy, 0103 physical sciences, medicine, Polymethyl Methacrylate, Radiology, Nuclear Medicine and imaging, Radiometry, [PHYS]Physics [physics], Physics, Particle therapy, Radiological and Ultrasound Technology, 010308 nuclear & particles physics, dose monitoring, carbon ion beam, lyso, drift chamber, Carbon, Charged particle, Atomic physics, Monte Carlo Method, Beam (structure)

Abstract

The radiation used in hadrontherapy treatments interacts with the patient body producing secondary particles, either neutral or charged, that can be used for dose and Bragg peak monitoring and to provide a fast feedback on the treatment plans. Recent results obtained from the authors on simplified setups (mono-energetic primary beams interacting with homogeneous tissue-like target) have already indicated the correlation that exists between the flux of these secondaries coming from the target (e.g. protons and photons) and the position of the primary beam Bragg peak. In this paper, the measurements of charged particle fluxes produced by the interaction of a 220 MeV/u carbon ion beam at GSI, Darmstadt, with a polymethyl methacrylate target are reported. The emission region of protons (p), deuterons (d) and tritons (t) has been characterized using a drift chamber while the particle time-of-flight, used to compute the kinetic energy spectra, was measured with a LYSO scintillator. The energy released in the LYSO crystal was used for particle identification purposes. The measurements were repeated with the setup at 60° and 90° with respect to the primary beam direction. The accuracy on the fragments emission profile reconstruction and its relationship with the Bragg peak position have been studied. Based on the acquired experimental evidence, a method to monitor the dose profile and the position of the Bragg peak inside the target is proposed. © 2014 Institute of Physics and Engineering in Medicine.

Published

2014

7. Secondary radiation measurements for particle therapy applications: charged particles produced by 4 He and 12 C ion beams in a PMMA target at large angle.

Author

Rucinski A, Battistoni G, Collamati F, De Lucia E, Faccini R, Frallicciardi PM, Mancini-Terracciano C, Marafini M, Mattei I, Muraro S, Paramatti R, Piersanti L, Pinci D, Russomando A, Sarti A, Sciubba A, Solfaroli Camillocci E, Toppi M, Traini G, Voena C, and Patera V

Subjects

Dose-Response Relationship, Radiation, Humans, Scattering, Radiation, Heavy Ion Radiotherapy adverse effects, Helium adverse effects, Polymethyl Methacrylate radiation effects, Radiation Monitoring methods, Radiotherapy Planning, Computer-Assisted methods

Abstract

Proton and carbon ion beams are used in the clinical practice for external radiotherapy treatments achieving, for selected indications, promising and superior clinical results with respect to x-ray based radiotherapy. Other ions, like [Formula: see text] have recently been considered as projectiles in particle therapy centres and might represent a good compromise between the linear energy transfer and the radiobiological effectiveness of [Formula: see text] ion and proton beams, allowing improved tumour control probability and minimising normal tissue complication probability. All the currently used p, [Formula: see text] and [Formula: see text] ion beams allow achieving sharp dose gradients on the boundary of the target volume, however the accurate dose delivery is sensitive to the patient positioning and to anatomical variations with respect to photon therapy. This requires beam range and/or dose release measurement during patient irradiation and therefore the development of dedicated monitoring techniques. All the proposed methods make use of the secondary radiation created by the beam interaction with the patient and, in particular, in the case of [Formula: see text] ion beams are also able to exploit the significant charged radiation component. Measurements performed to characterise the charged secondary radiation created by [Formula: see text] and [Formula: see text] particle therapy beams are reported. Charged secondary yields, energy spectra and emission profiles produced in a poly-methyl methacrylate (PMMA) target by [Formula: see text] and [Formula: see text] beams of different therapeutic energies were measured at 60° and 90° with respect to the primary beam direction. The secondary yield of protons produced along the primary beam path in a PMMA target was obtained. The energy spectra of charged secondaries were obtained from time-of-flight information, whereas the emission profiles were reconstructed exploiting tracking detector information. The obtained measurements are in agreement with results reported in the literature and suggests the feasibility of range monitoring based on charged secondary particle detection: the implications for particle therapy monitoring applications are also discussed.

Published

2018

8. Addendum: Measurement of charged particle yields from PMMA irradiated by a 220 MeV/u 12 C beam.

Author

Mattei I, Battistoni G, Collini F, De Lucia E, Durante M, Fiore S, Latessa C, Mancini-Terracciano C, Marafini M, Mirabelli R, Muraro S, Paramatti R, Piersanti L, Rucinski A, Russomando A, Sarti A, Schuy C, Sciubba A, Solfaroli Camillocci E, Toppi M, Traini G, Valle SM, Vanstalle M, and Patera V

Abstract

In this paper we report the re-analysis of the data published in (Piersanti et al. 2014) documenting the charged secondary particles production induced by the interaction of a 220 MeV/u 12C ion beam impinging on a polymethyl methacrylate (PMMA) target, measured in 2012 at the GSI facility in Darmstadt (Germany). This re-analysis takes into account the inhomogeneous light response of the LYSO crystal in the experimental setup measured in a subsequent experiment (2014) performed in the Heidelberg Ion- Beam Therapy Center. A better description of the detector and re-calculation of the geometrical efficiencies have been implemented as well, based on an improved approach that accounts also for the energy dependence of the emission spectrum. The new analysis has small effect on the total secondary charged flux, but has an impact on the production yield and emission velocity distributions of the different particle species (protons, deuterons and tritons) at different angles with respect to the beam direction (60° and 90°). All these observables indeed depend on the particle identification algorithms and hence on the LYSO detector energy response. The results of the data re-analysis presented here are intended to supersede and replace the results published in (Piersanti et al. 2014)., (© 2017 Institute of Physics and Engineering in Medicine.)

Published

2017

9. Secondary radiation measurements for particle therapy applications: nuclear fragmentation produced by 4 He ion beams in a PMMA target.

Author

Marafini M, Paramatti R, Pinci D, Battistoni G, Collamati F, De Lucia E, Faccini R, Frallicciardi PM, Mancini-Terracciano C, Mattei I, Muraro S, Piersanti L, Rovituso M, Rucinski A, Russomando A, Sarti A, Sciubba A, Solfaroli Camillocci E, Toppi M, Traini G, Voena C, and Patera V

Subjects

Algorithms, Humans, Monte Carlo Method, Protons, Radiotherapy Planning, Computer-Assisted, Relative Biological Effectiveness, Helium therapeutic use, Phantoms, Imaging, Polymethyl Methacrylate chemistry, Radiation Monitoring methods, Software

Abstract

Nowadays there is a growing interest in particle therapy treatments exploiting light ion beams against tumors due to their enhanced relative biological effectiveness and high space selectivity. In particular promising results are obtained by the use of 4 He projectiles. Unlike the treatments performed using protons, the beam ions can undergo a fragmentation process when interacting with the atomic nuclei in the patient body. In this paper the results of measurements performed at the Heidelberg Ion-Beam Therapy center are reported. For the first time the absolute fluxes and the energy spectra of the fragments-protons, deuterons, and tritons-produced by 4 He ion beams of 102, 125 and 145 MeV u -1 energies on a poly-methyl methacrylate target were evaluated at different angles. The obtained results are particularly relevant in view of the necessary optimization and review of the treatment planning software being developed for clinical use of 4 He beams in clinical routine and the relative bench-marking of Monte Carlo algorithm predictions.

Published

2017

10. Secondary radiation measurements for particle therapy applications: prompt photons produced by 4 He, 12 C and 16 O ion beams in a PMMA target.

Author

Mattei I, Bini F, Collamati F, De Lucia E, Frallicciardi PM, Iarocci E, Mancini-Terracciano C, Marafini M, Muraro S, Paramatti R, Patera V, Piersanti L, Pinci D, Rucinski A, Russomando A, Sarti A, Sciubba A, Solfaroli Camillocci E, Toppi M, Traini G, Voena C, and Battistoni G

Subjects

Carbon chemistry, Carbon therapeutic use, Heavy Ion Radiotherapy adverse effects, Heavy Ion Radiotherapy standards, Helium chemistry, Helium therapeutic use, Humans, Linear Energy Transfer, Proton Therapy, Relative Biological Effectiveness, Scintillation Counting instrumentation, Heavy Ion Radiotherapy methods, Photons, Polymethyl Methacrylate radiation effects, Scintillation Counting methods

Abstract

Charged particle beams are used in particle therapy (PT) to treat oncological patients due to their selective dose deposition in tissues with respect to the photons and electrons used in conventional radiotherapy. Heavy (Z  >  1) PT beams can additionally be exploited for their high biological effectiveness in killing cancer cells. Nowadays, protons and carbon ions are used in PT clinical routines. Recently, interest in the potential application of helium and oxygen beams has been growing. With respect to protons, such beams are characterized by their reduced multiple scattering inside the body, increased linear energy transfer, relative biological effectiveness and oxygen enhancement ratio. The precision of PT demands online dose monitoring techniques, crucial to improving the quality assurance of any treatment: possible patient mis-positioning and biological tissue changes with respect to the planning CT scan could negatively affect the outcome of the therapy. The beam range confined in the irradiated target can be monitored thanks to the neutral or charged secondary radiation emitted by the interactions of hadron beams with matter. Among these secondary products, prompt photons are produced by nuclear de-excitation processes, and at present, different dose monitoring and beam range verification techniques based on prompt-γ detection are being proposed. It is hence of importance to perform γ yield measurement in therapeutic-like conditions. In this paper we report on the yields of prompt photons produced by the interaction of helium, carbon and oxygen ion beams with a poly-methyl methacrylate (PMMA) beam stopping target. The measurements were performed at the Heidelberg Ion-Beam Therapy Center (HIT) with beams of different energies. An LYSO scintillator, placed at [Formula: see text] and [Formula: see text] with respect to the beam direction, was used as the photon detector. The obtained γ yields for the carbon ion beams are compared with results from the literature, while no other results from helium and oxygen beams have been published yet. A discussion on the expected resolution of a slit camera detector is presented, demonstrating the feasibility of a prompt-γ-based monitoring technique for PT treatments using helium, carbon and oxygen ion beams.

Published

2017