Your search keyword '"Silvia Muraro"' showing total 27 results

1. Monitoring Carbon Ion Beams Transverse Position Detecting Charged Secondary Fragments: Results From Patient Treatment Performed at CNAO

Author

Marco Toppi, Guido Baroni, Giuseppe Battistoni, Maria Giuseppina Bisogni, Piergiorgio Cerello, Mario Ciocca, Patrizia De Maria, Micol De Simoni, Marco Donetti, Yunsheng Dong, Alessia Embriaco, Veronica Ferrero, Elisa Fiorina, Marta Fischetti, Gaia Franciosini, Aafke Christine Kraan, Carmela Luongo, Etesam Malekzadeh, Marco Magi, Carlo Mancini-Terracciano, Michela Marafini, Ilaria Mattei, Enrico Mazzoni, Riccardo Mirabelli, Alfredo Mirandola, Matteo Morrocchi, Silvia Muraro, Vincenzo Patera, Francesco Pennazio, Angelo Schiavi, Adalberto Sciubba, Elena Solfaroli-Camillocci, Giancarlo Sportelli, Sara Tampellini, Giacomo Traini, Serena Marta Valle, Barbara Vischioni, Viviana Vitolo, and Alessio Sarti

Subjects

particle therapy, carbon ions, online monitoring, charged particles, fibre detectors, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Particle therapy in which deep seated tumours are treated using 12C ions (Carbon Ions RadioTherapy or CIRT) exploits the high conformity in the dose release, the high relative biological effectiveness and low oxygen enhancement ratio of such projectiles. The advantages of CIRT are driving a rapid increase in the number of centres that are trying to implement such technique. To fully profit from the ballistic precision achievable in delivering the dose to the target volume an online range verification system would be needed, but currently missing. The 12C ions beams range could only be monitored by looking at the secondary radiation emitted by the primary beam interaction with the patient tissues and no technical solution capable of the needed precision has been adopted in the clinical centres yet. The detection of charged secondary fragments, mainly protons, emitted by the patient is a promising approach, and is currently being explored in clinical trials at CNAO. Charged particles are easy to detect and can be back-tracked to the emission point with high efficiency in an almost background-free environment. These fragments are the product of projectiles fragmentation, and are hence mainly produced along the beam path inside the patient. This experimental signature can be used to monitor the beam position in the plane orthogonal to its flight direction, providing an online feedback to the beam transverse position monitor chambers used in the clinical centres. This information could be used to cross-check, validate and calibrate, whenever needed, the information provided by the ion chambers already implemented in most clinical centres as beam control detectors. In this paper we study the feasibility of such strategy in the clinical routine, analysing the data collected during the clinical trial performed at the CNAO facility on patients treated using 12C ions and monitored using the Dose Profiler (DP) detector developed within the INSIDE project. On the basis of the data collected monitoring three patients, the technique potential and limitations will be discussed.

Published

2021

2. The MONDO Tracker: Characterisation and Study of Secondary Ultrafast Neutrons Production in Carbon Ion Radiotherapy

Author

Marco Toppi, Giuseppe Battistoni, Alessandro Bochetti, Patrizia De Maria, Micol De Simoni, Yunsheng Dong, Marta Fischetti, Gaia Franciosini, Leonardo Gasparini, Marco Magi, Enrico Manuzzato, Ilaria Mattei, Riccardo Mirabelli, Silvia Muraro, Luca Parmesan, Vincenzo Patera, Matteo Perenzoni, Alessio Sarti, Angelo Schiavi, Adalberto Sciubba, Giacomo Traini, Serena Marta Valle, and Michela Marafini

Subjects

neutron tracking, particle therapy, carbon ions radiotherapy, secondary radiation monitoring, SPAD technology, Physics, QC1-999

Abstract

Secondary neutrons produced in particle therapy (PT) treatments are responsible for the delivery of a large fraction of the out-of-target dose as they feebly interact with the patient body. To properly account for their contribution to the total dose delivered to the patient, a high precision experimental characterisation of their production energy and angular distributions is eagerly needed. The experimental challenge posed by the detection and tracking of such neutrons will be addressed by the MONDO tracker: a compact scintillating fiber detector exploiting single and double elastic scattering interactions allowing for a complete neutron four-momentum reconstruction. To achieve a high detection efficiency while matching the fiber (squared, 250 μm side) high granularity, a single photon sensitive readout has been developed using the CMOS-based SPAD technology. The readout sensor, with pixels of 125×250 μm2 size, will be organised in tiles covering the full detector surface and will implement an autotrigger strategy to identify the events of interest. The expected detector performance in the context of neutron component characterisation in PT treatments delivered using carbon ions has been evaluated using a Monte Carlo simulation accounting for the detector response and the neutrons production spectra.

Published

2020

3. Detection of Interfractional Morphological Changes in Proton Therapy: A Simulation and In Vivo Study With the INSIDE In-Beam PET

Author

Elisa Fiorina, Veronica Ferrero, Guido Baroni, Giuseppe Battistoni, Nicola Belcari, Niccolo Camarlinghi, Piergiorgio Cerello, Mario Ciocca, Micol De Simoni, Marco Donetti, Yunsheng Dong, Alessia Embriaco, Marta Fischetti, Gaia Franciosini, Giuseppe Giraudo, Aafke Kraan, Francesco Laruina, Carmela Luongo, Davide Maestri, Marco Magi, Giuseppe Magro, Etesam Malekzadeh, Carlo Mancini Terracciano, Michela Marafini, Ilaria Mattei, Enrico Mazzoni, Paolo Mereu, Riccardo Mirabelli, Alfredo Mirandola, Matteo Morrocchi, Silvia Muraro, Alessandra Patera, Vincenzo Patera, Francesco Pennazio, Alessandra Retico, Angelo Rivetti, Manuel Dionisio Da Rocha Rolo, Valeria Rosso, Alessio Sarti, Angelo Schiavi, Adalberto Sciubba, Elena Solfaroli Camillocci, Giancarlo Sportelli, Sara Tampellini, Marco Toppi, Giacomo Traini, Serena Marta Valle, Francesca Valvo, Barbara Vischioni, Viviana Vitolo, Richard Wheadon, and Maria Giuseppina Bisogni

Subjects

adaptive therapy, Computer science, Materials Science (miscellaneous), medicine.medical_treatment, Monte Carlo method, Biophysics, General Physics and Astronomy, 030218 nuclear medicine & medical imaging, in vivo treatment verification, 03 medical and health sciences, 0302 clinical medicine, In vivo, Robustness (computer science), in-beam pet, medicine, proton therapy, range monitoring, Physical and Theoretical Chemistry, Radiation treatment planning, Proton therapy, Mathematical Physics, Monte Carlo simulation, Particle therapy, medicine.diagnostic_test, business.industry, clinical trial, lcsh:QC1-999, Positron emission tomography, 030220 oncology & carcinogenesis, Nuclear medicine, business, Beam (structure), lcsh:Physics

Abstract

In particle therapy, the uncertainty of the delivered particle range during the patient irradiation limits the optimization of the treatment planning. Therefore, an in vivo treatment verification device is required, not only to improve the plan robustness, but also to detect significant interfractional morphological changes during the treatment itself. In this article, an effective and robust analysis to detect regions with a significant range discrepancy is proposed. This study relies on an in vivo treatment verification by means of in-beam Positron Emission Tomography (PET) and was carried out with the INSIDE system installed at the National Center of Oncological Hadrontherapy (CNAO) in Pavia, which is under clinical testing since July 2019. Patients affected by head-and-neck tumors treated with protons have been considered. First, in order to tune the analysis parameters, a Monte Carlo (MC) simulation was carried out to reproduce a patient who required a replanning because of significant morphological changes found during the treatment. Then, the developed approach was validated on the experimental measurements of three patients recruited for the INSIDE clinical trial (ClinicalTrials.govID: NCT03662373), showing the capability to estimate the treatment compliance with the prescription both when no morphological changes occurred and when a morphological change did occur, thus proving to be a promising tool for clinicians to detect variations in the patients treatments.

Published

2021

4. Charge identification of fragments with the emulsion spectrometer of the FOOT experiment

Author

Maria Ionica, Eleuterio Spiriti, P. Carra, N. Bartosik, L. Scavarda, Osamu Sato, Adele Lauria, G. Silvestre, Alberto Del Guerra, Giovanni Ambrosi, Valeri Tioukov, Maria Cristina Montesi, Maria Giuseppina Bisogni, Nadia Pastrone, Alberto Clozza, S. Savazzi, M. Pullia, Alessandra Pastore, Antonio Zoccoli, M. Vanstalle, A. Moggi, E. Bellinzona, V. Lante, Elisa Fiorina, Antonia Di Crescenzo, A. Secher, Ilaria Mattei, Stefano Argiro, Giovanni De Lellis, Antonio Iuliano, Giuliana Galati, Chiara La Tessa, V. Gentile, Gaia Franciosini, Matteo Morrocchi, Luciano Ramello, R. Ridolfi, Giacomo Traini, Silvia Muraro, M. Selvi, Francesco Pennazio, Marco Francesconi, Michela Marafini, Alessio Sarti, A.C. Kraan, Marco Durante, M. Toppi, Pisana Placidi, S. Colombi, F. Raffaelli, C. Finck, Andrey Alexandrov, Christoph Schuy, Valeria Rosso, Adalberto Sciubba, Keida Kanxheri, Behcet Alpat, Nicola Belcari, Leonello Servoli, Sandro Tomassini, Achim Stahl, Angelo Schiavi, Giancarlo Sportelli, Ulrich Weber, Benedetto Di Ruzza, Luca Galli, R. Spighi, E. Iarocci, Martina Laurenza, Roberto Zarrella, Graziano Bruni, Raul Arteche Diaz, S. M. Valle, Y. Dong, Veronica Ferrero, R. Hetzel, Riccardo Faccini, Ernesto Lopez Torres, Silvia Biondi, Giuseppe Battistoni, Mario Sitta, M. Fischetti, Micol De Simoni, E. Scifoni, M. C. Morone, Giuseppe Giraudo, Marco Donetti, Gabriella Sartorelli, Vincenzo Patera, Federica Murtas, Alberto Mengarelli, Francesco Tommasino, E. Fiandrini, Esther Ciarrocchi, Mauro Villa, Matteo Franchini, Piergiorgio Cerello, Cristian Massimi, C. Sanelli, Galati G., Alexandrov A., Alpat B., Ambrosi G., Argiro S., Diaz R.A., Bartosik N., Battistoni G., Belcari N., Bellinzona E., Biondi S., Bisogni M.G., Bruni G., Carra P., Cerello P., Ciarrocchi E., Clozza A., Colombi S., Guerra A.D., Simoni M.D., Di Crescenzo A., Ruzza B.D., Donetti M., Dong Y., Durante M., Faccini R., Ferrero V., Fiandrini E., Finck C., Fiorina E., Fischetti M., Francesconi M., Franchini M., Franciosini G., Galli L., Gentile V., Giraudo G., Hetzel R., Iarocci E., Ionica M., Iuliano A., Kanxheri K., Kraan A.C., Lante V., Tessa C.L., Laurenza M., Lauria A., Torres E.L., Marafini M., Massimi C., Mattei I., Mengarelli A., Moggi A., Montesi M.C., Morone M.C., Morrocchi M., Muraro S., Murtas F., Pastore A., Pastrone N., Patera V., Pennazio F., Placidi P., Pullia M., Raffaelli F., Ramello L., Ridolfi R., Rosso V., Sanelli C., Sarti A., Sartorelli G., Sato O., Savazzi S., Scavarda L., Schiavi A., Schuy C., Scifoni E., Sciubba A., Secher A., Selvi M., Servoli L., Silvestre G., Sitta M., Spighi R., Spiriti E., Sportelli G., Stahl A., Tioukov V., Tomassini S., Tommasino F., Toppi M., Traini G., Valle S.M., Vanstalle M., Villa M., Weber U., Zarrella R., Zoccoli A., De Lellis G., De Lellis, Giovanni, Di Crescenzo, Antonia, Montesi, Maria Cristina, Lauria, Adele, Iuliano, Antonio, and Durante, Marco

Subjects

Materials science, Spectrometer, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, Physics, QC1-999, Settore FIS/07, Analytical chemistry, General Physics and Astronomy, Charge (physics), 01 natural sciences, Fragmentation (mass spectrometry), particle therapy, nuclear emulsion, fragmentation, 0103 physical sciences, Emulsion, ddc:530, Nuclear emulsion, Nuclear Experiment, 010306 general physics

Abstract

Open physics 19(1), 383 - 394 (2021). doi:10.1515/phys-2021-0032, Published by de Gruyter, Berlin

Published

2021

5. Challenges in Monte Carlo Simulations as Clinical and Research Tool in Particle Therapy: A Review

Author

Silvia Muraro, A.C. Kraan, and Giuseppe Battistoni

Subjects

treatment planning, Dose calculation, Materials Science (miscellaneous), medicine.medical_treatment, Monte Carlo method, Biophysics, General Physics and Astronomy, Field (computer science), 030218 nuclear medicine & medical imaging, 03 medical and health sciences, computing, 0302 clinical medicine, medicine, In patient, Patient treatment, Physical and Theoretical Chemistry, Monte Carlo, Mathematical Physics, Particle therapy, lcsh:QC1-999, particle therapy, radiobiology, 030220 oncology & carcinogenesis, Related research, Systems engineering, nuclear interactions, lcsh:Physics

Abstract

The use and interest in Monte Carlo (MC) techniques in the field of medical physics have been rapidly increasing in the past years. This is the case especially in particle therapy, where accurate simulations of different physics processes in complex patient geometries are crucial for a successful patient treatment and for many related research and development activities. Thanks to the detailed implementation of physics processes in any type of material, to the capability of tracking particles in 3D, and to the possibility of including the most important radiobiological effects, MC simulations have become an essential calculation tool not only for dose calculations but also for many other purposes, like the design and commissioning of novel clinical facilities, shielding and radiation protection, the commissioning of treatment planning systems, and prediction and interpretation of data for range monitoring strategies. MC simulations are starting to be more frequently used in clinical practice, especially in the form of specialized codes oriented to dose calculations that can be performed in short time. The use of general purpose MC codes is instead more devoted to research. Despite the increased use of MC simulations for patient treatments, the existing literature suggests that there are still a number of challenges to be faced in order to increase the accuracy of MC calculations for patient treatments. The goal of this review is to discuss some of these remaining challenges. Undoubtedly, it is a work for which a multidisciplinary approach is required. Here, we try to identify some of the aspects where the community involved in applied nuclear physics, radiation biophysics, and computing development can contribute to find solutions. We have selected four specific challenges: i) the development of models in MC to describe nuclear physics interactions, ii) modeling of radiobiological processes in MC simulations, iii) developments of MC-based treatment planning tools, and iv) developments of fast MC codes. For each of them, we describe the underlying problems, present selected examples of proposed solutions, and try to give recommendations for future research.

Published

2020

6. Scintillating Fiber Devices for Particle Therapy Applications

Author

M. Toppi, Alessio Sarti, R. Mirabelli, S. M. Valle, M. Marafini, V. Giacometti, Giacomo Traini, E. Gioscio, Carlo Mancini-Terracciano, A. Embriaco, M. Fischetti, Ilaria Mattei, M. De Simoni, Vincenzo Patera, A. Sciubba, G. Battistoni, Y. Dong, E. Solfaroli Camillocci, Marco Magi, and Silvia Muraro

Subjects

Nuclear and High Energy Physics, Materials science, Monitoring, medicine.medical_treatment, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, medicine, Calibration, Ion beams, Ions, Medical treatment, Neutrons, Photonics, Nuclear Energy and Engineering, Electrical and Electronic Engineering, Dosimetry, Neutron, Range (particle radiation), Particle therapy, business.industry, Detector, 030220 oncology & carcinogenesis, business, Beam (structure)

Abstract

Particle therapy (PT) is a radiation therapy technique in which solid tumors are treated with charged ions and exploits the achievable highly localized dose delivery, allowing to spare healthy tissues and organs at risk. The development of a range monitoring technique to be used online, during the treatment, capable to reach millimetric precision is considered one of the important steps toward an optimization of the PT efficacy and of the treatment quality. To this aim, charged secondary particles produced in the nuclear interactions between the beam particles and the patient tissues can be exploited. Besides charged secondaries, neutrons are also produced in nuclear interactions. The secondary neutron component might cause an undesired and not negligible dose deposition far away from the tumor region, enhancing the risk of secondary malignant neoplasms that can develop even years after the treatment. An accurate neutron characterization (flux, energy and emission profile) is, hence, needed for a better evaluation of long-term complications. In this contribution, two tracker detectors, both based on scintillating fibers, are presented. The first one, named dose profiler (DP), is planned to be used as a beam range monitor in PT treatments with heavy ion beams, exploiting the charged secondary fragments production. The DP is currently under development within the Innovative Solutions for In-Beam DosimEtry in Hadrontherapy project. The second one is dedicated to the measurement of the fast and ultrafast neutron component produced in PT treatments, in the framework of the monitor for neutron dose in hadrontherapy project. Results of the first calibration tests performed at the Trento Protontherapy Center and at Centro Nazionale di Adroterapia Oncologica (Italy) are reported, as well as simulation studies.

Published

2018

7. Inter-fractional monitoring of 12 C ions treatments: results from a clinical trial at the CNAO facility

Author

Marco Donetti, Vincenzo Patera, Etesam Malekzadeh, A. Sciubba, Piergiorgio Cerello, P. De Maria, Carlo Mancini-Terracciano, Angelo Schiavi, Ilaria Mattei, Matteo Morrocchi, Aafke Kraan, Francesco Pennazio, Alessio Sarti, G. Battistoni, A. Embriaco, Alfredo Mirandola, Gaia Franciosini, M. Marafini, Viviana Vitolo, Mario Ciocca, G. Bisogni, R. Mirabelli, M. Toppi, Erika Mazzoni, M. Fischetti, M. De Simoni, S. M. Valle, F. Galante, E. Solfaroli Camillocci, Y. Dong, B. Di Lullo, Guido Baroni, Veronica Ferrero, Barbara Vischioni, Elisa Fiorina, Giancarlo Sportelli, Sara Tampellini, Giacomo Traini, C. Luongo, Marco Magi, and Silvia Muraro

Subjects

medicine.medical_specialty, Particle Therapy, Monitoring, Carbon Ions, Fiber tracker, Monitoring, medicine.medical_treatment, Carbon, Clinical Trials as Topic, Humans, Ions, Radiometry, Radiotherapy Planning, Computer-Assisted, Radiotherapy Planning, Healthy tissue, Fiber tracker, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Computer-Assisted, Carbon Ions, medicine, Dosimetry, Medical physics, Radiation treatment planning, Carbon ion, Multidisciplinary, Particle therapy, business.industry, Monitoring system, Clinical routine, Clinical trial, Particle Therapy, 030220 oncology & carcinogenesis, business

Abstract

The high dose conformity and healthy tissue sparing achievable in Particle Therapy when using C ions calls for safety factors in treatment planning, to prevent the tumor under-dosage related to the possible occurrence of inter-fractional morphological changes during a treatment. This limitation could be overcome by a range monitor, still missing in clinical routine, capable of providing on-line feedback. The Dose Profiler (DP) is a detector developed within the INnovative Solution for In-beam Dosimetry in hadronthErapy (INSIDE) collaboration for the monitoring of carbon ion treatments at the CNAO facility (Centro Nazionale di Adroterapia Oncologica) exploiting the detection of charged secondary fragments that escape from the patient. The DP capability to detect inter-fractional changes is demonstrated by comparing the obtained fragment emission maps in different fractions of the treatments enrolled in the first ever clinical trial of such a monitoring system, performed at CNAO. The case of a CNAO patient that underwent a significant morphological change is presented in detail, focusing on the implications that can be drawn for the achievable inter-fractional monitoring DP sensitivity in real clinical conditions. The results have been cross-checked against a simulation study.

Published

2020

8. Development of a novel neutron tracker for the characterisation of secondary neutrons emitted in Particle Therapy

Author

M. Toppi, Adalberto Sciubba, Silvia Muraro, G. Battistoni, E. Gioscio, A. Schiavi, Ilaria Mattei, Michela Marafini, M. Fischetti, Vincenzo Patera, Y. Dong, Alessio Sarti, A. Bochetti, M. De Simoni, Giacomo Traini, R. Mirabelli, and S. M. Valle

Subjects

Physics, Elastic scattering, Nuclear and High Energy Physics, Particle therapy, Proton, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, medicine.medical_treatment, Detector, Neutron radiation, Tracking (particle physics), 01 natural sciences, double elastic scattering, Optics, 0103 physical sciences, secondary neutrons, tracking detector, medicine, Neutron, Monochromatic color, 010306 general physics, business, Instrumentation

Abstract

The MONDO (MOnitor for Neutron Dose in hadrOntherapy) project addresses the technical challenges posed by a neutron tracker detector: high detection efficiency and good backtracking precision. The project main goal is to develop a tracking device capable of fully reconstructing the four-momentum of the ultra-fast secondary neutrons produced in Particle Therapy treatments via double elastic scattering interactions. The tracker – a 16 × 16 × 20 cm 3 matrix – is made by a matrix of thin squared scintillating fibres (250 μ m ) arranged in layers orthogonally oriented. A custom readout system called SBAM (SPAD-Based Acquisition readout for MONDO experiment), matched to the MONDO needs of single photon detection capability, high spatial resolution and compactness, has been developed in collaboration with Fondazione Bruno Kessler (FBK). A small detector prototype ( 4 × 4 × 4 . 8 cm 3 ) has been built and tested with a sensor prototype, SPADnet-I, in order to experimentally evaluate the light output expected and consequently optimise the final readout. The simulation characterisation of the detector response with monochromatic neutrons in the [20-300] MeV will be presented together with the expected performances of MONDO as neutron beam monitor. The preliminary measurements at electron and proton beams of the prototype with the SPAD array readout will be reported.

Published

2020

9. FOOT: a new experiment to measure nuclear fragmentation at intermediate energies

Author

M. Pullia, E. Iarocci, Nadia Pastrone, C. La Tessa, M. Emde, M. Rovituso, Alberto Clozza, C. Sanelli, M. C. Morone, A. Di Crescenzo, G. Ambrosi, L. Narici, Giancarlo Sportelli, Veronica Ferrero, Francesco Tommasino, Matteo Franchini, Maria Cristina Montesi, M. Ionica, Stefano Argiro, Niccolò Camarlinghi, R. Faccini, Mauro Villa, Gabriella Sartorelli, Antonio Zoccoli, L. Galli, M. Vanstalle, K. Kanxheri, Christoph Schuy, Esther Ciarrocchi, Vincenzo Patera, A. Sciubba, Marco Durante, Valeria Rosso, M. Selvi, Ilaria Mattei, M. Sitta, M. Garbini, Uli Weber, Matteo Morrocchi, Giacomo Traini, Marco Francesconi, Piergiorgio Cerello, Eleuterio Spiriti, Nicola Belcari, S. Brambilla, L. Ramello, R. Hetzel, C. Finck, Andrey Alexandrov, Silvia Biondi, Giuseppe Battistoni, Osamu Sato, Adele Lauria, M. Marafini, Giuseppe Giraudo, R. Mirabelli, R. Spighi, F. Ferroni, Silvia Muraro, Leonello Servoli, Achim Stahl, S. M. Valle, G. De Lellis, Graziano Bruni, Angelo Schiavi, Alessio Sarti, Maria Giuseppina Bisogni, E. Scifoni, Alessandra Pastore, 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), Université Louis Pasteur - Strasbourg I-Centre National de la Recherche Scientifique (CNRS), Valle, S.M., Alexandrov, A., Ambrosi, G., Argirò, S., Battistoni, G., Belcari, N., Biondi, S., Bisogni, M.G., Bruni, G., Brambilla, S., Camarlinghi, N., Cerello, P., Ciarrocchi, E., Clozza, A., De Lellis, G., Di Crescenzo, A., Durante, M., Emde, M., Faccini, R., Ferrero, V., Ferroni, F., Finck, C., Francesconi, M., Franchini, M., Galli, L., Garbini, M., Giraudo, G., Hetzel, R., Iarocci, E., Ionica, M., Kanxheri, K., Lauria, A., La Tessa, C., Marafini, M., Mattei, I., Mirabelli, R., Montesi, M.C., Morone, M.C., Morrocchi, M., Muraro, S., Narici, L., Pastore, A., Pastrone, N., Patera, V., Pullia, M., Ramello, L., Rosso, V., Rovituso, M., Sanelli, C., Sarti, A., Sartorelli, G., Sato, O., Schiavi, A., Schuy, C., Scifoni, E., Sciubba, A., Selvi, M., Servoli, L., Sitta, M., Spighi, R., Spiriti, E., Sportelli, G., Stahl, A., Tommasino, F., Traini, G., Vanstalle, M., Villa, M., Weber, U., Zoccoli, A., Valle, S. M., Bisogni, M. G., Montesi, M. C., and Morone, M. C.

Subjects

Materials science, Tracking detector, medicine.medical_treatment, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Bragg peak, Scintillator, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Nuclear physics, Fragmentation (mass spectrometry), Hadrontherapy, 0103 physical sciences, medicine, lcsh:Science, lcsh:Science (General), 010306 general physics, Nuclear Experiment, Particle therapy, cross section, 010308 nuclear & particles physics, Projectile, Settore FIS/04, Settore FIS/07, Nuclear fragmentation, Scintillating detectors, Charged particle, Time of flight, Physics::Accelerator Physics, lcsh:Q, Beam (structure), lcsh:Q1-390

Abstract

Summary: Charged particle therapy exploits proton or 12C beams to treat deep-seated solid tumors. Due to the advantageous characteristics of charged particles energy deposition in matter, the maximum of the dose is released to the tumor at the end of the beam range, in the Bragg peak region. However, the beam nuclear interactions with the patient tissues induces fragmentation both of projectile and target nuclei and needs to be carefully taken into account. In proton treatments, target fragmentation produces low energy, short range fragments along all the beam range, which deposit a non negligible dose in the entry channel. In 12C treatments the main concern is represented by long range fragments due to beam fragmentation that release their dose in the healthy tissues beyond the tumor. The FOOT experiment (FragmentatiOn Of Target) of INFN is designed to study these processes, in order to improve the nuclear fragmentation description in next generation Treatment Planning Systems and the treatment plans quality. Target (16O and 12C nuclei) fragmentation induced by –proton beams at therapeutic energies will be studied via an inverse kinematic approach, where 16O and 12C therapeutic beams impinge on graphite and hydrocarbon targets to provide the nuclear fragmentation cross section on hydrogen. Projectile fragmentation of 16O and 12C beams will be explored as well. The FOOT detector includes a magnetic spectrometer for the fragments momentum measurement, a plastic scintillator for ΔE and time of flight measurements and a crystal calorimeter to measure the fragments kinetic energy. These measurements will be combined in order to make an accurate fragment charge and isotopic identification. Keywords: Hadrontherapy, Nuclear fragmentation cross sections, Tracking detectors, Scintillating detectors

Published

2019

10. Nuclear physics and particle therapy

Author

G. Battistoni, I. Mattei, and Silvia Muraro

Subjects

Physics, Particle therapy, Quantitative Biology::Tissues and Organs, medicine.medical_treatment, Nuclear Theory, Physics::Medical Physics, Monte Carlo method, Cancer therapy, General Physics and Astronomy, Charged particle, 030218 nuclear medicine & medical imaging, Nuclear physics, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, Medical imaging, medicine, Nuclear Experiment

Abstract

The use of charged particles and nuclei in cancer therapy is one of the most successful cases of application of nuclear physics to medicine. The physical advantages in terms of precision and select...

Published

2016

11. Development and characterization of a ΔE-TOF detector prototype for the FOOT experiment

Author

R. Hetzel, Silvia Biondi, Giuseppe Battistoni, Alessandra Pastore, M. Pullia, Marco Francesconi, Giovanni De Lellis, M. C. Morone, Pisana Placidi, Giuseppe Giraudo, Mario Sitta, Alberto Mengarelli, Graziano Bruni, Nicola Belcari, Adalberto Sciubba, E. Fiandrini, Niccolò Camarlinghi, A.C. Kraan, S. Colombi, Esther Ciarrocchi, Maria Ionica, A. Embriaco, Eleuterio Spiriti, Nadia Pastrone, Livio Narici, N. Bartosik, Alberto Del Guerra, Christoph Schuy, Sebastian Hild, P. Carra, L. Scavarda, M. Selvi, V. Lante, Elisa Fiorina, G. Silvestre, Sandro Tomassini, Osamu Sato, Adele Lauria, Behcet Alpat, Stefano Argiro, Marco Durante, Valeria Rosso, Giancarlo Sportelli, M. G. Bisogni, F. Ferroni, M. Emde, Ulrich Weber, R. Mirabelli, Veronica Ferrero, Francesco Pennazio, Keida Kanxheri, G. Ambrosi, M. Garbini, Valeri Tioukov, Alessio Sarti, R. Ridolfi, Giacomo Traini, Leonello Servoli, Achim Stahl, M. Fischetti, Raul Arteche Diaz, Silvia Muraro, S. M. Valle, Antonia Di Crescenzo, Micol De Simoni, M. Rovituso, Chiara La Tessa, C. Finck, Matteo Bertazzoni, Andrey Alexandrov, Alberto Clozza, S. Savazzi, Y. Dong, E. Scifoni, V. Gentile, Ilaria Mattei, Marco Donetti, Gabriella Sartorelli, Matteo Morrocchi, M. Villa, Vincenzo Patera, Luciano Ramello, A. Schiavi, Roberto Spighi, Piergiorgio Cerello, L. Galli, C. Sanelli, Maria Cristina Montesi, Riccardo Faccini, M. Marafini, Ernesto Lopez Torres, Antonio Zoccoli, M. Vanstalle, Francesco Tommasino, Matteo Franchini, Morrocchi, Matteo, Ciarrocchi, Esther, Alexandrov, Andrey, Alpat, Behcet, Ambrosi, Giovanni, Argirò, Stefano, Arteche Diaz, Raul, Bartosik, Nazar, Battistoni, Giuseppe, Belcari, Nicola, Bertazzoni, Matteo, Biondi, Silvia, Bruni, Graziano, Camarlinghi, Niccolò, Carra, Pietro, Cerello, Piergiorgio, Clozza, Alberto, Colombi, Sofia, De Lellis, Giovanni, Del Guerra, Alberto, Simoni, Micol De, Crescenzo, Antonia Di, Donetti, Marco, Dong, Yunsheng, Durante, Marco, Embriaco, Alessia, Emde, Max, Faccini, Riccardo, Ferrero, Veronica, Ferroni, Fernando, Fiandrini, Emanuele, Finck, Christian, Fiorina, Elisa, Fischetti, Marta, Francesconi, Marco, Franchini, Matteo, Galli, Luca, Garbini, Marco, Gentile, Valerio, Giraudo, Giuseppe, Hetzel, Ronja, Hild, Sebastian, Ionica, Maria, Kanxheri, Keida, Kraan, Aafke Christine, Lante, Valeria, Lauria, Adele, La Tessa, Chiara, Lopez Torres, Ernesto, Marafini, Michela, Mattei, Ilaria, Mengarelli, Alberto, Mirabelli, Riccardo, Montesi, Maria Cristina, Morone, Maria Cristina, Muraro, Silvia, Narici, Livio, Pastore, Alessandra, Pastrone, Nadia, Patera, Vincenzo, Pennazio, Francesco, Placidi, Pisana, Pullia, Marco, Ramello, Luciano, Ridolfi, Riccardo, Rosso, Valeria, Rovituso, Marta, Sanelli, Claudio, Sarti, Alessio, Sartorelli, Gabriella, Sato, Osamu, Savazzi, Simone, Scavarda, Lorenzo, Schiavi, Angelo, Schuy, Christoph, Scifoni, Emanuele, Sciubba, Adalberto, Selvi, Marco, Servoli, Leonello, Silvestre, Gianluigi, Sitta, Mario, Spighi, Roberto, Spiriti, Eleuterio, Sportelli, Giancarlo, Stahl, Achim, Tomassini, Sandro, Tommasino, Francesco, Traini, Giacomo, Tioukov, Valeri, Valle, Serena Marta, Vanstalle, Marie, Villa, Mauro, Weber, Ulrich, Zoccoli, Antonio, Bisogni, Maria Giuseppina, Istituto Nazionale di Fisica Nucleare, Sezione di Milano (INFN), Istituto Nazionale di Fisica Nucleare (INFN), Département de Radiobiologie, Hadronthérapie et Imagerie Moléculaire (DRHIM-IPHC), 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)-Université de Strasbourg (UNISTRA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Max-Planck-Institut für Quantenoptik (MPQ), Max-Planck-Gesellschaft, Istituto Nazionale di Fisica Nucleare, Sezione di Perugia (INFN, Sezione di Perugia), Department of Basic and Applied Sciences for Engineering, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], INFN Istituto Nazionale di Fisica Nucleare [Frascati], Dipartimento di Scienze di Base e Applicate per l'Ingegneria (SBAI), Université de Strasbourg (UNISTRA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Union Internationale des Transports Publics (UITP), and UITP

Subjects

Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, Particle therapy, Particle detectors, Particle detectors Particle therapy Plastic scintillator Silicon photomultiplier, Scintillator, Silicon photomultiplier, Kinetic energy, 01 natural sciences, Ion, Settore FIS/04 - Fisica Nucleare e Subnucleare, Optics, 0103 physical sciences, Plastic scintillator, Instrumentation, Irradiation, 010306 general physics, Image resolution, Particle detectors, Particle therapy, Plastic scintillator, Silicon photomultiplier, [PHYS]Physics [physics], Physics, 010308 nuclear & particles physics, business.industry, Detector, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), Time of flight, High Energy Physics::Experiment, business

Abstract

This paper describes the development and characterization of a Δ E-TOF detector composed of a plastic scintillator bar coupled at both ends to silicon photomultipliers. This detector is a prototype of a larger version which will be used in the FOOT (FragmentatiOn Of Target) experiment to identify the fragments produced by ion beams accelerated onto a hydrogen-enriched target. The final Δ E-TOF detector will be composed of two layers of plastic scintillator bars with orthogonal orientation and will measure, for each crossing fragment, the energy deposited in the plastic scintillator ( Δ E), the time of flight (TOF), and the coordinates of the interaction position in the scintillator. To meet the FOOT experimental requirements, the detector should have energy resolution of a few percents and time resolution of 70 ps, and it should allow to discriminate multiple fragments belonging to the same event. To evaluate the achievable performances, the detector prototype was irradiated with protons of kinetic energy in the 70–230 MeV range and interacting at several positions along the bar. The measured energy resolution σ Δ E ∕ Δ E was 6–14%, after subtracting the fluctuations of the deposited energy. A time resolution σ between 120 and 180 ps was obtained with respect to a trigger detector. A spatial resolution σ of 1.9 cm was obtained for protons interacting at the center of the bar.

Published

2019

12. Review and performance of the Dose Profiler, a particle therapy treatments online monitor

Author

Y. Dong, G. Battistoni, S. M. Valle, A. Embriaco, Ilaria Mattei, A. Schiavi, M. De Simoni, Alessio Sarti, R. Mirabelli, M. Fischetti, Giacomo Traini, Marco Magi, Silvia Muraro, Carlo Mancini-Terracciano, Vincenzo Patera, A. Sciubba, E. Solfaroli Camillocci, Maria Giuseppina Bisogni, and M. Marafini

Subjects

Quality Control, Photon, Materials science, Radiation monitoring, Proton, medicine.medical_treatment, Nuclear engineering, Biophysics, General Physics and Astronomy, Heavy Ion Radiotherapy, Context (language use), Online Systems, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Instrumentation for heavy-ion therapy, Particle tracking detectors, medicine, Relative biological effectiveness, Humans, Radiology, Nuclear Medicine and imaging, Radiometry, Range (particle radiation), Particle therapy, Detector, General Medicine, 030220 oncology & carcinogenesis

Abstract

Particle therapy (PT) can exploit heavy ions (such as He, C or O) to enhance the treatment efficacy, profiting from the increased Relative Biological Effectiveness and Oxygen Enhancement Ratio of these projectiles with respect to proton beams. To maximise the gain in tumor control probability a precise online monitoring of the dose release is needed, avoiding unnecessary large safety margins surroundings the tumor volume accounting for possible patient mispositioning or morphological changes with respect to the initial CT scan. The Dose Profiler (DP) detector, presented in this manuscript, is a scintillating fibres tracker of charged secondary particles (mainly protons) that will be operating during the treatment, allowing for an online range monitoring. Such monitoring technique is particularly promising in the context of heavy ions PT, in which the precision achievable by other techniques based on secondary photons detection is limited by the environmental background during the beam delivery. Developed and built at the SBAI department of "La Sapienza", within the INSIDE collaboration and as part of a Centro Fermi flagship project, the DP is a tracker detector specifically designed and planned for clinical applications inside a PT treatment room. The DP operation in clinical like conditions has been tested with the proton and carbon ions beams of Trento proton-therapy center and of the CNAO facility. In this contribution the detector performances are presented, in the context of the carbon ions monitoring clinical trial that is about to start at the CNAO centre.

Published

2019

13. THE FOOT EXPERIMENT: FRAGMENTATION MEASUREMENTS IN PARTICLE THERAPY

Author

E. Bellinzona, Nadia Pastrone, Alessandro Pastore, E. López Torres, M. Selvi, L. Alunni Solestizi, Pisana Placidi, E. Iarocci, F. Ferroni, Silvia Muraro, C. La Tessa, M. C. Morone, E. Spiriti, M. Ionica, P. Cerello, Y. Dong, R. Arteche Diaz, A. Zoccoli, A. Secher, Giuliana Galati, V. Lante, Elisa Fiorina, Christoph Schuy, M. De Simoni, M. Vanstalle, Luciano Ramello, K. Kanxheri, Stefano Argiro, S. M. Valle, M. Donetti, M. Garbini, A. C. Kraan, R. Ridolfi, Alberto Mengarelli, Marco Durante, N. Bartosik, A. Moggi, Valeria Rosso, M. Emde, Giacomo Traini, Angelo Schiavi, F. Raffaeli, Niccolò Camarlinghi, M. Pullia, M. Francesconi, G. De Lellis, L. Scavarda, M. Franchini, Mario Sitta, M. Villa, E. Fiandrini, M. Rovituso, Ilaria Mattei, R. Faccini, Alberto Clozza, S. Savazzi, Gabriella Sartorelli, Graziano Bruni, Matteo Morrocchi, Esther Ciarrocchi, Vincenzo Patera, A. Di Crescenzo, A. Sciubba, A. Del Guerra, G. Ambrosi, Valeri Tioukov, M. Fischetti, Veronica Ferrero, E. Scifoni, Francesco Pennazio, Livio Narici, Osamu Sato, Alessio Sarti, Adele Lauria, Francesco Tommasino, S. Colombi, Giancarlo Sportelli, M. G. Bisogni, A. Stahl, V. Gentile, S. Bianucci, R. Mirabelli, Leonello Servoli, U. Weber, Luca Galli, R. Spighi, Nicola Belcari, M. Marafini, A. Embriaco, C. Sanelli, S. Tommasini, C. Finck, Maria Cristina Montesi, P. Carra, G. Silvestre, A. Alexandrov, R. Hetzel, Silvia Biondi, Giuseppe Battistoni, Giuseppe Giraudo, A. Alexandrov, L. Alunni Solestizi, G. Ambrosi, S. Argirò, R. Arteche Diaz, N. Bartosik, G. Battistoni, N. Belcari, E. Bellinzona, S. Bianucci, S. Biondi, M. G. Bisogni, G. Bruni, N. Camarlinghi, P. Carra, P. Cerello, E. Ciarrocchi, A. Clozza, S. Colombi, G. De Lellis, A. Del Guerra, M. De Simoni, A. Di Crescenzo, M. Donetti, Y. Dong, M. Durante, A. Embriaco, M. Emde, R. Faccini, V. Ferrero, F. Ferroni, E. Fiandrini, C. Finck, E. Fiorina, M. Fischetti, M. Francesconi, M. Franchini, G. Galati, L. Galli, M. Garbini, V. Gentile, G. Giraudo, R. Hetzel, E. Iarocci, M. Ionica, K. Kanxheri, A. C. Kraan, V. Lante, A. Lauria, C. La Tessa, E. Lopez Torres, M. Marafini, I. Mattei, A. Mengarelli, R. Mirabelli, A. Moggi, M. C. Montesi, M. C. Morone, M. Morrocchi, S. Muraro, L. Narici, A. Pastore, N. Pastrone, V. Patera, F. Pennazio, P. Placidi, M. Pullia, F. Raffaeli, L. Ramello, R. Ridolfi, V. Rosso, M. Rovituso, C. Sanelli, A. Sarti, G. Sartorelli, O. Sato, S. Savazzi, L. Scavarda, A. Schiavi, C. Schuy, E. Scifoni, A. Sciubba, A. Sécher, M. Selvi, L. Servoli, G. Silvestre, M. Sitta, R. Spighi, E. Spiriti, G. Sportelli, A. Stahl, V. Tioukov, S. Tommasini, F. Tommasino, G. Traini, S. M. Valle, M. Vanstalle, M. Villa, U. Webe, A. Zoccoli, Alexandrov, A., Alunni Solestizi, L., Ambrosi, G., Argirò, S., Arteche Diaz, R., Bartosik, N., Battistoni, G., Belcari, N., Bellinzona, E., Bianucci, S., Biondi, S., Bisogni, M. G., Bruni, G., Camarlinghi, N., Carra, P., Cerello, P., Ciarrocchi, E., Clozza, A., Colombi, S., De Lellis, G., Del Guerra, A., De Simoni, M., Di Crescenzo, A., Donetti, M., Dong, Y., Durante, M., Embriaco, A., Emde, M., Faccini, R., Ferrero, V., Ferroni, F., Fiandrini, E., Finck, C., Fiorina, E., Fischetti, M., Francesconi, M., Franchini, M., Galati, G., Galli, L., Garbini, M., Gentile, V., Giraudo, G., Hetzel, R., Iarocci, E., Ionica, M., Kanxheri, K., Kraan, A. C., Lante, V., Lauria, A., La Tessa, C., Lopez Torres, E., Marafini, M., Mattei, I., Mengarelli, A., Mirabelli, R., Moggi, A., Montesi, M. C., Morone, M. C., Morrocchi, M., Muraro, S., Narici, L., Pastore, A., Pastrone, N., Patera, V., Pennazio, F., Placidi, P., Pullia, M., Raffaeli, F., Ramello, L., Ridolfi, R., Rosso, V., Rovituso, M., Sanelli, C., Sarti, A., Sartorelli, G., Sato, O., Savazzi, S., Scavarda, L., Schiavi, A., Schuy, C., Scifoni, E., Sciubba, A., Sécher, A., Selvi, M., Servoli, L., Silvestre, G., Sitta, M., Spighi, R., Spiriti, E., Sportelli, G., Stahl, A., Tioukov, V., Tommasini, S., Tommasino, F., Traini, G., Valle, S. M., Vanstalle, M., Villa, M., Weber, U., and Zoccoli, A.

Subjects

Nuclear physics, Particle therapy, Materials science, Physics::Instrumentation and Detectors, medicine.medical_treatment, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Media Technology, medicine, Fragmentation (computing), Nuclear Experiment, fragmentation, hadrotherapy, cross section, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin)

Abstract

Charged Particle Therapy (CPT) is a powerful radiotherapy technique for the treatment of deep-seated tumours characterized by a large dose released in the Bragg peak area (corresponding to the tumour region) and a small dose delivered to the surrounding healthy tissues. The precise measurement of the fragments produced in the nuclear interactions of charged particle beams with patient tissues is a crucial task to improve the clinical treatment plans. The FOOT (FragmentatiOn Of Target) experiment is an international project, funded by the Istituto Nazionale di Fisica Nucleare (INFN), aimed to study the dose released by the tissues and particle beams fragmentation. The target (16O, 12C) fragmentation induced by 150-400 MeV/n proton beams will be studied via the inverse kinematic approach, where 16O and 12C therapeutic beams collide on graphite and hydrocarbon target to provide the cross section on Hydrogen. A table-top detector is being developed and it includes a drift chamber as a beam monitor upstream of the target to measure the beam direction, a magnetic spectrometer based on silicon pixel and strip detectors, a scintillating crystal calorimeter able to stop the heavier produced fragments, and a ΔE detector, with TOF capability, for the particle identification. A setup based on the concept of the “Emulsion Cloud Chamber”, coupled with the interaction region of the electronic FOOT setup, will complement the physics program by measuring lighter charged fragments to extend the angular acceptance up to about 70 degrees. In this work, the experimental design and the requirements of the FOOT experiment will be discussed and preliminary results on the emulsion spectrometer tests will be presented.

Published

2019

14. Secondary radiation measurements for particle therapy applications: Charged secondaries produced by 16O ion beams in a PMMA target at large angles

Author

Alessio Sarti, E. Gioscio, S. M. Valle, A. Baratto Roldan, Giacomo Traini, M. Fischetti, G. Battistoni, Ilaria Mattei, Silvia Muraro, Antoni Rucinski, Y. Dong, M. De Simoni, P.M. Frallicciardi, R. Mirabelli, A. Schiavi, M. Marafini, E. Solfaroli Camillocci, Vincenzo Patera, A. Sciubba, and Carlo Mancini-Terracciano

Subjects

Materials science, medicine.medical_treatment, Physics::Medical Physics, Oxygen beams, Biophysics, General Physics and Astronomy, Particle therapy, Bragg peak, Radiation, Secondary radiation, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Optics, medicine, Range monitoring, Radiology, Nuclear Medicine and imaging, Irradiation, Range (particle radiation), business.industry, General Medicine, Charged particle, 030220 oncology & carcinogenesis, Particle, business

Abstract

Particle therapy is a therapy technique that exploits protons or light ions to irradiate tumor targets with high accuracy. Protons and 12C ions are already used for irradiation in clinical routine, while new ions like 4He and 16O are currently being considered. Despite the indisputable physical and biological advantages of such ion beams, the planning of charged particle therapy treatments is challenged by range uncertainties, i.e. the uncertainty on the position of the maximal dose release (Bragg Peak - BP), during the treatment. To ensure correct 'in-treatment' dose deposition, range monitoring techniques, currently missing in light ion treatment techniques, are eagerly needed. The results presented in this manuscript indicate that charged secondary particles, mainly protons, produced by an 16O beam during target irradiation can be considered as candidates for 16O beam range monitoring. Hereafter, we report on the first yield measurements of protons, deuterons and tritons produced in the interaction of an 16O beam impinging on a PMMA target, as a function of detected energy and particle production position. Charged particles were detected at 90° and 60° with respect to incoming beam direction, and homogeneous and heterogeneous PMMA targets were used to probe the sensitivity of the technique to target inhomogeneities. The reported secondary particle yields provide essential information needed to assess the accuracy and resolution achievable in clinical conditions by range monitoring techniques based on secondary charged radiation.

Published

2019

15. Fragment charge identification technique with a plastic scintillator detector using clinical carbon beams

Author

Matteo Morrocchi, L. Galli, Giuseppe Battistoni, Nicola Belcari, A. Moggi, Valeria Rosso, P. Carra, Esther Ciarrocchi, Silvia Muraro, Maria Giuseppina Bisogni, M. Francesconi, A. Del Guerra, Niccolò Camarlinghi, A.C. Kraan, M. Pullia, and Giancarlo Sportelli

Subjects

Physics, Nuclear and High Energy Physics, Particle therapy, Dose calculation, medicine.medical_treatment, Charge identification, Nuclear fragmentation, Particle therapy, Time-of-flight, Time-of-flight, Physics::Medical Physics, Monte Carlo method, Detector, Nuclear fragmentation, Scintillator, 030218 nuclear medicine & medical imaging, Ion, Nuclear physics, 03 medical and health sciences, Time of flight, 0302 clinical medicine, Fragmentation (mass spectrometry), Charge identification, 030220 oncology & carcinogenesis, medicine, Instrumentation

Abstract

Nuclear physics processes are an important source of uncertainty in dose calculations in particle therapy and radioprotection in space. Accurate cross section measurements are a crucial ingredient in improving the understanding of these processes. The FOOT (FragmentatiOn Of Target) experiment aims at measuring the production cross sections of fragments for energies, beams and targets that are relevant in particle therapy and radioprotection in space. An experimental apparatus composed of several sub-detectors will provide the mass, charge, velocity and energy of fragments produced in nuclear interactions in a thin target. A crucial component of the FOOT apparatus will be the Δ E-TOF detector, designed to identify the charge of the fragments using plastic scintillators to measure the energy deposited and the time of flight with respect to a start counter. In this work, we present a charge reconstruction procedure of produced fragments at particle therapy energies. We validate it by measuring the charges of various fragments at an angle of 3.2°and 8.3°with respect the beam-axis, using a small-scale detector and clinical beams of carbon ions at the CNAO oncology center. Experimental results agree well with FLUKA Monte Carlo simulations.

Published

2019

16. In-room performance evaluation of a novel online charged secondary particles monitor of light ions PT treatments

Author

Angelo Schiavi, Michela Marafini, Alessio Sarti, Carlo Mancini-Terracciano, Giuseppe Battistoni, Yunshen Dong, Vincenzo Patera, Eliana Gioscio, R. Mirabelli, M. Fischetti, Micol De Simoni, Elena Solfaroli Camillocci, Silvia Muraro, S. M. Valle, Ilaria Mattei, Adalberto Sciubba, and Giacomo Traini

Subjects

Range (particle radiation), Materials science, Particle therapy, business.industry, medicine.medical_treatment, Detector, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Optics, 030220 oncology & carcinogenesis, Relative biological effectiveness, Oxygen enhancement ratio, medicine, Beam direction, business, Beam (structure)

Abstract

The advantages of using C, He and O ions as therapeutical beam particles in Particle Therapy is related to their enhanced Relative Biological Effectiveness and Oxygen Enhancement Ratio, resulting in an improved efficacy in damaging the cancerous cells. However, an accurate on-line control of the dose release spatial distribution is required to spare the healthy tissues surrounding the tumor area, preventing undesired damages caused by, for example, morphological changes occurred in the patient during the treatment with respect to the initial CT scan. This monitor technology is currently missing in clinical practice, and several studies are being performed to develop beam range verification systems exploiting the detection of the emitted secondary radiation. Charged secondary particles, produced by the projectile fragmentation in the collisions with the patient tissues, represent an interesting chance for C, He and O treatments since they are also emitted at large angles with respect to the beam direction and can be detected with high efficiency in a nearly background free environment. The Dose Profiler detector is a scintillating fibre tracker that allows an online charged fragments reconstruction and backtracking. The construction and preliminary tests performed on the DP, carried out using the Carbon ions beam of the CNAO treatment centre using an anthropomorphic phantom as a target, will be reviewed in this contribution.

Published

2018

17. Charged particles and neutron trackers: Applications to particle therapy

Author

Giacomo Traini, E. Solfaroli Camillocci, Carlo Mancini-Terracciano, E. Gioscio, G. Battistoni, M. Fischetti, S. M. Valle, Vincenzo Patera, A. Sciubba, M. De Simoni, R. Mirabelli, Y. Dong, Alessio Sarti, Ilaria Mattei, Silvia Muraro, A. Embriaco, and M. Marafini

Subjects

Physics, Nuclear and High Energy Physics, Particle therapy, business.industry, medicine.medical_treatment, Physics::Medical Physics, 020208 electrical & electronic engineering, Bragg peak, 02 engineering and technology, Charged particle, Neutron temperature, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Optics, Charged particles, Fast neutrons, Range monitoring, Scintillating fibers, 0202 electrical engineering, electronic engineering, information engineering, medicine, Relative biological effectiveness, Neutron, business, Instrumentation, Beam (structure)

Abstract

The use of C, He and O as beam particles in Particle Therapy (PT) treatments is getting more and more widespread as a consequence of the enhanced relative biological effectiveness and oxygen enhancement ratio of such projectiles with respect to protons. The advantages in the tumor control probability, related to the improved efficacy of ions, are calling for an online monitor of the dose release spatial distribution. Such technology is currently missing in PT treatments clinical routine. In this contribution the status of Z > 1 ions PT treatments monitoring, exploiting the detection of either charged secondary particles or neutrons, is reviewed. While charged fragments can be used to provide an online feedback to the beam control system, by correlating their emission profile with the position of the Bragg peak, neutrons have to be monitored to improve the experimental description of the secondary radiation component that significantly contributes to an undesired and not negligible dose deposition far away from the tumor region, enhancing the risk of secondary malignancies development after the treatment. Two tracker detectors, employing scintillating fibers , are presented: the Dose Profiler designed for charged secondary fragments measurements and the MONDO tracker dedicated to the characterisation of the secondary fast and ultrafast neutron component, within the MONDO (MOnitor for Neutron Dose in hadrOntherapy) project.

Published

2020

18. The FOOT (Fragmentation Of Target) Experiment

Author

M. Garbini, Angelo Schiavi, Giacomo Traini, Valery Tioukov, Esther Ciarrocchi, Alessandra Pastore, Cristiana Peroni, Luciano Ramello, M. Franchini, M. Vanstalle, M. C. Morone, Niccolò Camarlinghi, Riccardo Paramatti, Nadia Pastrone, Giancarlo Sportelli, M. G. Bisogni, Alessio Sarti, Michela Marafini, C. Sanelli, Emanuele Scifoni, A. Zoccoli, Graziano Bruni, E. Iarocci, C. Finck, Andrey Alexandrov, Gabriella Sartorelli, Vincenzo Patera, M. Selvi, Christoph Schuy, M. Pullia, Piergiorgio Cerello, Maria Cristina Montesi, Sergio Brambilla, Marco Durante, Mario Sitta, Marianna Testa, Valeria Rosso, Eleuterio Spiriti, Silvia Biondi, Giuseppe Battistoni, Stefano Argiro, Keida Kanxheri, Leonello Servoli, Chiara La Tessa, Nicola Belcari, Riccardo Faccini, Marco Francesconi, Livio Narici, Luca Galli, Antonia Di Crescenzo, Francesco Tommasino, Giuseppe Giraudo, R. Spighi, F. Ferroni, Ilaria Mattei, Matteo Morrocchi, R. Mirabelli, Giovanni De Lellis, M. Rovituso, Adalberto Sciubba, Alberto Clozza, Silvia Muraro, Osamu Sato, Adele Lauria, Veronica Ferrero, S. M. Valle, Ulrich Weber, M. Villa, Institut Pluridisciplinaire Hubert Curien (IPHC), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS), and Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Proton, Physics::Instrumentation and Detectors, medicine.medical_treatment, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Bragg peak, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Particle identification, 030218 nuclear medicine & medical imaging, Ion, Nuclear physics, 03 medical and health sciences, 0302 clinical medicine, 0103 physical sciences, medicine, Nuclear Experiment, Hadron therapy nuclear fragmentation, Physics, Particle therapy, 010308 nuclear & particles physics, Projectile, Settore FIS/07, Charged particle, Physics::Accelerator Physics, Beam (structure)

Abstract

Particle therapy uses protons or $^{12}$C beams for the treatment of deep-seated solid tumors. Due to the features of the energy deposition of charged particles in matter, a limited amount of dose is released to the healthy tissue in the beam entrance region, while the maximum of the dose is released to the tumor at the end of the beam range, in the Bragg peak region. However nuclear interactions between beam and patient tissues induce fragmentation both of projectile and target. This has to be carefully taken into account since different ions have different effectiveness in producing a biological damage. par In $^{12}$C treatments the main concern are long range forward emitted secondary ions produced in projectile fragmentation that release dose in the healthy tissue after the tumor. Instead, in a proton treatment, the target fragmentation produces low energy, short range fragments along all the beam range. The FOOT experiment (FragmentatiOn Of Target) is designed to study these processes. Target nuclei ($^{16}$O, $^{12}$C) fragmentation induced by 150-250 MeV proton beam will be studied by means of the inverse kinematic approach: $^{16}$O,$^{12}$C therapeutic beams, at the quoted kinetic energy per nucleon, collide on graphite and hydrocarbons target. The cross section on Hydrogen can be then extracted by subtraction. This configuration explores also the projectile fragmentation of these O and C beams, or other ions of therapeutic interest, such as $^4$He for instance. The detector includes a magnetic spectrometer based on silicon pixel and strip detectors, a scintillating crystal calorimeter able to stop the heavier produced fragments, and a $\Delta E$ detector, with TOF capability, to achieve the needed energy resolution and particle identification. In addition to the electronic apparatus, an alternative setup based on the concept of the "Emulsion Cloud Chamber", coupled with the interaction region of the electronic FOOT setup, will provide the measurement of lighter charged fragments: protons, deuterons, tritons and Helium nuclei. The FOOT data taking is foreseen in the available experimental rooms existing in the presently operational charged particle therapy facilities in Europe, and possibly at GSI. An initial phase with the emulsion setup will start in early 2018, while the complete electronic detector will take data starting in 2019. In this work a general description of the FOOT experiment and of its expected performances is presented.

Published

2017

19. A Monte Carlo approach to the microdosimetric kinetic model to account for dose rate time structure effects in ion beam therapy with application in treatment planning simulations

Author

L Manganaro, Andrea Attili, Silvia Muraro, Vincenzo Monaco, Simona Giordanengo, G. V. Russo, Roberto Sacchi, Anna Vignati, Roberto Cirio, and F. Dalmasso

Subjects

Materials science, Radiobiology, Ion beam, medicine.medical_treatment, Monte Carlo method, Radiation Dosage, Models, Biological, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Cell Line, Tumor, Relative biological effectiveness, medicine, Humans, Irradiation, Statistical physics, Radiometry, Stochastic Processes, Particle therapy, Stochastic process, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, General Medicine, Kinetics, 030220 oncology & carcinogenesis, Monte Carlo Method, Relative Biological Effectiveness

Abstract

Purpose Advanced ion beam therapeutic techniques, such as hypofractionation, respiratory gating, or laser-based pulsed beams, have dose rate time structures which are substantially different from those found in conventional approaches. The biological impact of the time structure is mediated through the β parameter in the linear quadratic (LQ) model. The aim of this study was to assess the impact of changes in the value of the β parameter on the treatment outcomes, also accounting for noninstantaneous intrafraction dose delivery or fractionation and comparing the effects of using different primary ions. Methods An original formulation of the microdosimetric kinetic model (MKM) is used (named MCt-MKM), in which a Monte Carlo (MC) approach was introduced to account for the stochastic spatio-temporal correlations characteristic of the irradiations and the cellular repair kinetics. A modified version of the kinetic equations, validated on experimental cell survival in vitro data, was also introduced. The model, trained on the HSG cells, was used to evaluate the relative biological effectiveness (RBE) for treatments with acute and protracted fractions. Exemplary cases of prostate cancer irradiated with different ion beams were evaluated to assess the impact of the temporal effects. Results The LQ parameters for a range of cell lines (V79, HSG, and T1) and ion species (H, He, C, and Ne) were evaluated and compared with the experimental data available in the literature, with good results. Notably, in contrast to the original MKM formulation, the MCt-MKM explicitly predicts an ion and LET-dependent β compatible with observations. The data from a split-dose experiment were used to experimentally determine the value of the parameter related to the cellular repair kinetics. Concerning the clinical case considered, an RBE decrease was observed, depending on the dose, ion, and LET, exceeding up to 3% of the acute value in the case of a protraction in the delivery of 10 min. The intercomparison between different ions shows that the clinical optimality is strongly dependent on a complex interplay between the different physical and biological quantities considered. Conclusions The present study provides a framework for exploiting the temporal effects of dose delivery. The results show the possibility of optimizing the treatment outcomes accounting for the correlation between the specific dose rate time structure and the spatial characteristic of the LET distribution, depending on the ion type used.

Published

2017

20. 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

Riccardo Paramatti, E. Iarocci, Fabiano Bini, A. Russomando, Vincenzo Patera, Silvia Muraro, Alessio Sarti, A. Sciubba, M. Marafini, M. Toppi, P.M. Frallicciardi, G. Battistoni, D. Pinci, E. De Lucia, Carlo Mancini-Terracciano, Francesco Collamati, E. Solfaroli Camillocci, C. Voena, Antoni Rucinski, Luca Piersanti, Giacomo Traini, and Ilaria Mattei

Subjects

Range (particle radiation), Materials science, Particle therapy, Physics - Instrumentation and Detectors, Radiological and Ultrasound Technology, medicine.medical_treatment, Physics::Medical Physics, Linear energy transfer, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), Heavy Ion Radiotherapy, Physics - Medical Physics, Charged particle, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, Relative biological effectiveness, medicine, Physics::Accelerator Physics, Radiology, Nuclear Medicine and imaging, Irradiation, Medical Physics (physics.med-ph), Atomic physics, Proton therapy

Abstract

Charged particle beams are used in Particle Therapy (PT) to treat oncological patients due to their selective dose deposition in tissues and to their high biological effect in killing cancer cells with respect to photons and electrons used in conventional radiotherapy. Nowadays, protons and carbon ions are used in PT clinical routine but, recently, the interest on the potential application of helium and oxygen beams is growing due to their reduced multiple scattering inside the body and increased linear energy transfer, relative biological effectiveness and oxygen enhancement ratio. The precision of PT demands for online dose monitoring techniques, crucial to improve the quality assurance of treatments. 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. Prompt photons are produced by nuclear de-excitation processes and, at present, different dose monitoring and beam range verification techniques based on the prompt {\gamma} detection have been proposed. It is hence of importance to perform the {\gamma} yield measurement in therapeutical-like conditions. In this paper we report the yields of prompt photons produced by the interaction of helium, carbon and oxygen ion beams with a PMMA target. The measurements were performed at the Heidelberg Ion-beam Therapy center (HIT) with beams of different energies. A LYSO scintillator has been used as photon detector. The obtained {\gamma} yields for $^{12}$C ion beams are compared with results from literature, while no other results from $^{4}$He and $^{16}$O beams have been published yet. A discussion on the expected resolution of a slit camera detector is presented, demonstrating the feasibility of a prompt-{\gamma} based monitoring technique for PT treatments using helium, carbon and oxygen ion beams., Comment: Submitted to PMB

Published

2016

21. Secondary radiation measurements for particle therapy applications: charged particles produced by4He and12C ion beams in a PMMA target at large angle

Author

D. Pinci, A. Russomando, R. Faccini, Luciano Piersanti, P.M. Frallicciardi, Silvia Muraro, M. Marafini, Vincenzo Patera, A. Sciubba, G. Battistoni, E. De Lucia, M. Toppi, Carlo Mancini-Terracciano, C. Voena, Antoni Rucinski, Francesco Collamati, Ilaria Mattei, Alessio Sarti, Giacomo Traini, E. Solfaroli Camillocci, and Riccardo Paramatti

Subjects

Physics, Range (particle radiation), Particle therapy, Radiological and Ultrasound Technology, Quantitative Biology::Tissues and Organs, medicine.medical_treatment, Physics::Medical Physics, Linear energy transfer, Radiation, Tracking (particle physics), Charged particle, 030218 nuclear medicine & medical imaging, Ion, Computational physics, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, medicine, Radiology, Nuclear Medicine and imaging, Beam (structure)

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

22. Measurement of secondary particle production induced by particle therapy ion beams impinging on a PMMA target

Author

Michela Marafini, G. Battistoni, Antoni Rucinski, F. Bellini, Alessio Sarti, E. Solfaroli Camillocci, M. Toppi, A. Russomando, Marco Durante, P.M. Frallicciardi, Ilaria Mattei, D. Pinci, M. Senzacqua, R. Faccini, Vincenzo Patera, A. Sciubba, Francesco Collamati, Luca Piersanti, Riccardo Paramatti, Silvia Muraro, Giacomo Traini, C. Voena, S. Morganti, and E. De Lucia

Subjects

Physics, Particle therapy, Ion beam, 010308 nuclear & particles physics, medicine.medical_treatment, Quantitative Biology::Tissues and Organs, QC1-999, Physics::Medical Physics, Particle Therapy, Monitoring online, Charged particles, 01 natural sciences, Charged particle, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Helium-4, 0103 physical sciences, medicine, Particle, Physics::Accelerator Physics, ddc:530, Irradiation, Atomic physics, Beam (structure)

Abstract

Particle therapy is a technique that uses accelerated charged ions for cancer treatment and combines a high irradiation precision with a high biological effectiveness in killing tumor cells [1]. Informations about the secondary particles emitted in the interaction of an ion beam with the patient during a treatment can be of great interest in order to monitor the dose deposition. For this purpose an experiment at the HIT (Heidelberg Ion-Beam Therapy Center) beam facility has been performed in order to measure fluxes and emission profiles of secondary particles produced in the interaction of therapeutic beams with a PMMA target. In this contribution some preliminary results about the emission profiles and the energy spectra of the detected secondaries will be presented.

Published

2016

23. The INSIDE project: Innovative solutions for in-beam dosimetry in hadrontherapy

Author

N. Belcari, C. Voena, Giuseppe Giraudo, A. Del Guerra, F. Ciciriello, G. Matarrese, R. Faccini, Niccolò Camarlinghi, Matteo Cecchetti, Cristoforo Marzocca, Vincenzo Patera, Silvia Muraro, Paola Sala, A. Sciubba, Francesco Pennazio, P.M. Frallicciardi, G. Battistoni, Alessio Sarti, Piergiorgio Cerello, Giacomo Cuttone, G. Pirrone, B. Liu, Matteo Morrocchi, C. Morone, E. Kostara, Giancarlo Sportelli, M. Marafini, Richard Wheadon, N. Marino, E. De Lucia, F. Licciulli, F. Corsi, Luca Piersanti, Angelo Rivetti, G.A.P. Cirrone, Elisa Fiorina, Fabrizio Romano, M.A. Piliero, Aafke Kraan, Andrea Attili, F. Cappucci, S. Coli, Valeria Rosso, S. Ferretti, Cristiana Peroni, and Maria Giuseppina Bisogni

Subjects

Bragg peak positions, Charged particles, media_common.quotation_subject, Social networking (online), General Physics and Astronomy, Particle therapy, Art, Innovative solutions, Particle Therapy, Monitoring online, Charged particles, Dose monitoring, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), Hadron therapy, Physics and Astronomy (all), Monitoring online, Dosimetry, Charged particles, Bragg peak positions, Particle therapy, Social networking (online), Humanities, media_common

Abstract

Dosimetry in Hadrontherapy M. Marafini, A. Attili, G. Battistoni, N. Belcari, M.G. Bisogni, N. Camarlinghi, F. Cappucci, M. Cecchetti, P. Cerello, F. Ciciriello , G.A.P. Cirrone, S. Coli, F. Corsi , G. Cuttone, E. De Lucia, S. Ferretti, R. Faccini, E. Fiorina, P.M. Frallicciardi, G. Giraudo, E. Kostara, A. Kraan, F. Licciulli , B. Liu, N. Marino, C. Marzocca , G. Matarrese , C. Morone, M. Morrocchi, S. Muraro, V. Patera, F. Pennazio, C. Peroni, L. Piersanti, M.A. Piliero, G. Pirrone, A. Rivetti, F. Romano, V. Rosso, P. Sala, A. Sarti, A. Sciubba, G. Sportelli, C. Voena, R. Wheadon and A. Del Guerra Museo Storico della Fisica e Centro Studi e Ricerche E. Fermi , Roma, Italy b−f INFN Sezione di: Roma, Roma; Torino, Torino; Milano, Milano; Pisa, Pisa; Bari, Bari; Italy Laboratori Nazionali del Sud dell'INFN, Catania, Italy Laboratori Nazionali di Frascati dell'INFN, Frascati, Italy Dipartimento di Scienze di Base e Applicate per Ingegneria, Sapienza Universita di Roma, Roma, Italy

Published

2015

24. Abstract ID: 67 MC codes and range monitoring in particle therapy: The case of secondary charged particles

Author

G. Battistoni, Carlo Mancini-Terracciano, M. Marafini, C. Voena, M. Toppi, R. Mirabelli, Vincenzo Patera, A. Sciubba, Ilaria Mattei, Alessio Sarti, S. M. Valle, E. Solfaroli Camillocci, Giacomo Traini, E. De Lucia, and Silvia Muraro

Subjects

Physics, Range (particle radiation), Particle therapy, Proton, business.industry, medicine.medical_treatment, Detector, Biophysics, General Physics and Astronomy, Cosmic ray, General Medicine, Scintillator, Charged particle, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, 030220 oncology & carcinogenesis, medicine, Dosimetry, Radiology, Nuclear Medicine and imaging, business

Abstract

Particle therapy planning gets fundamental information from MC codes. Its millimetric precision needs the assurance of the successfulness of the treatment session. Different range monitoring techniques are under development exploiting secondary particles which are generated in the patient during the treatment: prompt gammas, annihilation gammas from beta+ induced activity, charged fragments. The yield of produced particles and their propagation in the human tissue must be studied with MC codes. In this contribution, in the framework of the INSIDE collaboration (Innovative Solutions for In-beam Dosimetry in hadrontherapy), the case of secondary charged fragments emission during the treatment is considered [1] . A detector named Dose Profiler (DP), able to track secondary charged fragments (mainly protons) emitted at large angles with respect to the beam direction, is under construction and test. The tracker is made by six layers (20 × 20 cm2) of BCF-12 square scintillating fibres (500 μm) coupled to Silicon Photo-Multipliers, followed by two plastic scintillator layers of 6 mm thickness. The detector characterization with cosmic rays has been performed and a calibration data taking campaign with protons is currently undergoing. The attenuation of the secondary charged particles emission profile due to the crossed material is studied and parametrized with the FLUKA MC code. A full simulation of a treatment in a realistic patient-detector system and the secondary charged fragments reconstruction is presented. Track reconstruction is performed by means of a Kalman filter algorithm using the GenFit code. The on-line operation of DP requires the real-time reconstruction of the amount of material crossed in the patient by each detected proton. This task will be accomplished using FRED, a fast GPU-MC code.

Published

2017

25. 152: An integrated monitoring system for the on-line assessment of particle therapy treatment accuracy

Author

F. Licciulli, Paola Sala, F. Corsi, Alessio Sarti, R. Nicolini, Giancarlo Sportelli, Aafke Kraan, E. De Lucia, Valeria Rosso, N. Marino, Richard Wheadon, Matteo Morrocchi, Pasquale Delogu, Cristiana Peroni, Niccolò Camarlinghi, G.A.P. Cirrone, F. Ciciriello, N. Belcari, G. Pirrone, B. Liu, Elisa Fiorina, S. Ferretti, Silvia Muraro, Fabrizio Romano, Giacomo Cuttone, Cristoforo Marzocca, Angelo Rivetti, G. Matarrese, C. Morone, A. Del Guerra, R. Faccini, Vincenzo Patera, A. Sciubba, Maria Giuseppina Bisogni, Luciano Piersanti, S. Coli, P. Cerello, M.A. Piliero, Giuseppe Giraudo, and G. Battistoni

Subjects

Integrated monitoring, Particle therapy, Oncology, Computer science, medicine.medical_treatment, Real-time computing, medicine, Radiology, Nuclear Medicine and imaging, Hematology, Line (text file)

Published

2014

26. Realization of an innovative Dose Profiler for online range monitoring in particle therapy treatments

Author

M. Toppi, C. Voena, D. Pinci, A. Russomando, G. Battistoni, Silvia Muraro, Giacomo Traini, Michela Marafini, Antoni Rucinski, Ilaria Mattei, Francesco Collamati, Alessio Sarti, R. Faccini, Vincenzo Patera, A. Sciubba, E. Solfaroli Camillocci, Riccardo Paramatti, and E. De Lucia

Subjects

medicine.medical_specialty, Range (particle radiation), Particle therapy, Oncology, Radiology Nuclear Medicine and imaging, Computer science, medicine.medical_treatment, Electronic engineering, medicine, Radiology, Nuclear Medicine and imaging, Medical physics, Hematology, Realization (systems)

27. The Drift Chamber detector of the FOOT experiment: Performance analysis and external calibration

Author

Lante Valeria, M. G. Bisogni, Morrocchi Matteo, Sartorelli Gabriella, Fiandrini Emanuele, Mattei Ilaria, Colombi Sofia, Kanxheri Keida, Ionica Maria, Narici Livio, Spiriti Eleuterio, Giraudo Giuseppe, Laurenza Martina, Benedetto Di Ruzza, Argirò Stefano, Tomassini Sandro, Iarocci Enzo, Maria Cristina Montesi, Traini Giacomo, Mengarelli Alberto, Y. Dong, Sportelli Giancarlo, Ferrero Veronica, Antonia Di Crescenzo, Weber Ulrich, Schiavi Angelo, Alpat Behcet, Scifoni Emanuele, Franciosini Gaia, Spighi Roberto, Silvestre Gianluigi, Barbanera Mattia, Ciarrocchi Esther, Clozza Alberto, Chiara La Tessa, Pastore Alessandra, M. Villa, M. C. Morone, Alexandrov Andrey, Sato Osamu, Donetti Marco, Galli Luca, Ridolfi Riccardo, Massimi Cristian, Pastrone Nadia, Ernesto Lopez Torres, Sciubba Adalberto, Rosso Valeria, Cerello Piergiorgio, Alberto Del Guerra, Micol De Simoni, A.C. Kraan, Marafini Michela, Leonello Servoli, Ramello Luciano, Gentile Valerio, Raul Arteche Diaz, S. M. Valle, Pullia Marco, Galati Giuliana, Raffaelli Fabrizio, Franchini Matteo, Vincenzo Patera, Fiorina Elisa, Francesconi Marco, Savazzi Simone, Finck Christian, Toppi Marco, Pennazio Francesco, Selvi Marco, Schuy Christoph, Bellinzona Elettra, Durante Marco, Placidi Pisana, Giovanni De Lellis, Sanelli Claudio, Sécher Alexandre, Belcari Nicola, Bartosik Nazar, Francesco Tommasino, Sarti Alessio, Giuseppe Battistoni, Sitta Mario, Fischetti Marta, Ambrosi Giovanni, Valeri Tioukov, Hetzel Ronja, M. Vanstalle, Carra Pietro, Stahl Achim, Zoccoli Antonio, Muraro Silvia, Moggi Andrea, Lauria Adele, Bruni Graziano, Biondi Silvia, Scavarda Lorenzo, Dong Y., Gianluigi S., Sofia C., Andrey A., Behcet A., Giovanni A., Stefano A., Arteche Diaz R., Mattia B., Nazar B., Nicola B., Elettra B., S. Biondi, Bisogni M.G., G. Bruni, Pietro C., Piergiorgio C., Esther C., Alberto C., De Lellis G., Del Guerra A., De Simoni M., Di Crescenzo A., Di Ruzza B., Marco D., Veronica F., Emanuele F., Christian F., Elisa F., Marta F., Marco F., M. Franchini., Gaia F., Giuliana G., Luca G., Valerio G., Giuseppe G., Ronja H., Enzo I., Maria I., Keida K., Kraan A.C., Valeria L., La Tessa C., Martina L., Adele L., Lopez Torres E., Michela M., Cristian M., Ilaria M., A. Mengarelli, Andrea M., Montesi M.C., Morone M.C., Matteo M., Silvia M., Livio N., Alessandra P., Nadia P., Patera V., Francesco P., Pisana P., Marco P., Fabrizio R., Luciano R., R. Ridolfi, Valeria R., Claudio S., Alessio S., G. Sartorelli, Osamu S., Simone S., Lorenzo S., Angelo S., Christoph S., Emanuele S., Adalberto S., Alexandre S., Marco S., Mario S., R. Spighi, Eleuterio S., Giancarlo S., Achim S., Sandro T., Marco T., Giacomo T., Tioukov V., Valle S.M., Vanstalle M., Villa M., Ulrich W., A. Zoccoli, Battistoni G., Servoli L., Tommasino F., Dong, Yunsheng, Gianluigi, Silvestre, Sofia, Colombi, Alexandrov, Andrey, Behcet, Alpat, Giovanni, Ambrosi, Stefano, Argirò, Arteche Diaz, Raul, Mattia, Barbanera, Nazar, Bartosik, Nicola, Belcari, Elettra, Bellinzona, Silvia, Biondi, Bisogni, Maria Giuseppina, Graziano, Bruni, Pietro, Carra, Piergiorgio, Cerello, Esther, Ciarrocchi, Alberto, Clozza, De Lellis, Giovanni, Del Guerra, Alberto, De Simoni, Micol, Di Crescenzo, Antonia, Di Ruzza, Benedetto, Marco, Donetti, Durante, Marco, Veronica, Ferrero, Emanuele, Fiandrini, Christian, Finck, Elisa, Fiorina, Marta, Fischetti, Marco, Francesconi, Matteo, Franchini, Gaia, Franciosini, Galati, Giuliana, Luca, Galli, Valerio, Gentile, Giuseppe, Giraudo, Ronja, Hetzel, Enzo, Iarocci, Maria, Ionica, Keida, Kanxheri, Kraan, Aafke Christine, Valeria, Lante, La Tessa, Chiara, Martina, Laurenza, Lauria, Adele, Lopez Torres, Ernesto, Michela, Marafini, Cristian, Massimi, Ilaria, Mattei, Alberto, Mengarelli, Andrea, Moggi, Montesi, Maria Cristina, Morone, Maria Cristina, Matteo, Morrocchi, Silvia, Muraro, Livio, Narici, Alessandra, Pastore, Nadia, Pastrone, Patera, Vincenzo, Francesco, Pennazio, Pisana, Placidi, Marco, Pullia, Fabrizio, Raffaelli, Luciano, Ramello, Riccardo, Ridolfi, Valeria, Rosso, Claudio, Sanelli, Alessio, Sarti, Gabriella, Sartorelli, Osamu, Sato, Simone, Savazzi, Lorenzo, Scavarda, Angelo, Schiavi, Christoph, Schuy, Emanuele, Scifoni, Adalberto, Sciubba, Alexandre, Sécher, Marco, Selvi, Mario, Sitta, Roberto, Spighi, Eleuterio, Spiriti, Giancarlo, Sportelli, Achim, Stahl, Sandro, Tomassini, Marco, Toppi, Giacomo, Traini, Tioukov, Valeri, Valle, Serena Marta, Vanstalle, Marie, Villa, Mauro, Ulrich, Weber, Antonio, Zoccoli, Battistoni, Giuseppe, Servoli, Leonello, Tommasino, Francesco, Institut Pluridisciplinaire Hubert Curien (IPHC), and Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Nuclear and High Energy Physics, Silicon, Physics::Instrumentation and Detectors, medicine.medical_treatment, Nuclear physics, chemistry.chemical_element, 01 natural sciences, Microstrip, Optics, nuclear physics, Silicon microstrip detector, silicon microstrip detector, 0103 physical sciences, medicine, Perpendicular, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010306 general physics, Instrumentation, Image resolution, Physics, drift chamber, Particle therapy, 010308 nuclear & particles physics, Projectile, business.industry, Settore FIS/04, Settore FIS/07, Detector, chemistry, Nuclear physic, Drift chamber, business, Beam energy

Abstract

The study that we present is part of the preparation work for the setup of the FOOT (FragmentatiOn Of Target) experiment whose main goal is the measurement of the double differential cross sections of fragments produced in nuclear interactions of particles with energies relevant for particle therapy. The present work is focused on the characterization of the gas-filled drift chamber detector composed of 36 sensitive cells, distributed over two perpendicular views. Each view consists of six consecutive and staggered layers with three cells per layer. We investigated the detector efficiency and we performed an external calibration of the space–time relations at the level of single cells. This information was then used to evaluate the drift chamber resolution. An external tracking system realized with microstrip silicon detectors was adopted to have a track measurement independent on the drift chamber. The characterization was performed with a proton beam at the energies of 228 and 80 MeV. The overall hit detection efficiency of the drift chamber has been found to be 0 . 929 ± 0 . 008 , independent on the proton beam energy. The spatial resolution in the central part of the cell is about 150 ± 10 μ m and 300 ± 10 μ m and the corresponding detector angular resolution has been measured to be 1 . 62 ± 0 . 16 mrad and 2 . 1 ± 0 . 4 mrad for the higher and lower beam energies, respectively. In addition, the best value on the intrinsic drift chamber resolution has been evaluated to be in the range 60 − 100 μ m. In the framework of the FOOT experiment, the drift chamber will be adopted in the pre-target region, and will be exploited to measure the projectile direction and position, as well as for the identification of pre-target fragmentation events.

Published

2021