Your search keyword '"N. Matsufuji"' showing total 107 results

1. OC-0095 Neon minibeam radiotherapy (Ne MBRT): investigating biological mechanisms with synchrotron light

Author

I. Martínez-Rovira, O. Seksek, J. Bergs, R. Hirayama, N. Matsufuji, T. Inaniwa, S. Koike, T. Shimokawa, Y. Prezado, and I. Yousef

Subjects

Oncology, Radiology, Nuclear Medicine and imaging, Hematology

Published

2022

2. A Novel Track Imaging System as a Range Counter

Author

Atsushi Kitagawa, Toshiyuki Kohno, S. Kanayama, Yusuke Koba, A. Ishida, M. Sekiguchi, T. Murakami, N. Matsufuji, and Z. Chen

Subjects

Physics, Nuclear and High Energy Physics, medicine.medical_specialty, Range (particle radiation), Physics::Instrumentation and Detectors, business.industry, Track (disk drive), Ion track, Resolution (electron density), Detector, Scintillator, 030218 nuclear medicine & medical imaging, Ion, 03 medical and health sciences, 0302 clinical medicine, Optics, 030220 oncology & carcinogenesis, medicine, Medical physics, business, Instrumentation, Energy (signal processing)

Abstract

An image-intensified, camera-based track imaging system has been developed to measure the tracks of ions in a scintillator block. To study the performance of the detector unit in the system, two types of scintillators, a dosimetrically tissue-equivalent plastic scintillator EJ-240 and a CsI(Tl) scintillator, were separately irradiated with carbon ion ( 12 C) beams of therapeutic energy from HIMAC at NIRS. The images of individual ion tracks in the scintillators were acquired by the newly developed track imaging system. The ranges reconstructed from the images are reported here. The range resolution of the measurements is 1.8 mm for 290 MeV/u carbon ions, which is considered a significant improvement on the energy resolution of the conventional Δ E / E method. The detector is compact and easy to handle, and it can fit inside treatment rooms for in-situ studies, as well as satisfy clinical quality assurance purposes.

Published

2016

3. A Measurement Method of AC Losses in Superconducting Coils Using Poynting's Vector Method

Author

H. Higuchi, Akifumi Kawagoe, and N. Matsufuji

Subjects

Physics, Quantitative Biology::Biomolecules, Acoustics, Physics::Medical Physics, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Magnetic field, Search coil, Nuclear magnetic resonance, Coil noise, Electromagnetic coil, Electric field, Poynting vector, Electrical and Electronic Engineering, Rogowski coil, Coil tap

Abstract

A new measurement method to determine ac losses in superconducting coils has been proposed, and its validity confirmed experimentally. In this method, the ac losses in the coil can be obtained from measured Poynting's vectors around the coil windings. The Poynting's vectors can be obtained by local magnetic fields and electric fields around the coil. Local magnetic fields and electric fields are measured by pick-up coils and potential leads, which are mounted around the sample coil. These pick-up coil and potential lead pairs are arranged on the inner side, outer side, top, and bottom of the coil windings to cover the entire coil windings. This measurement method has the benefit that ac losses in a coil in a superconducting coil system consisting of multiple coils can be measured. Not only ac losses in the coils but also information on local electromagnetic phenomena in the coils can be obtained from profiles of the Poynting's vectors. In this paper, the details of the measuring method are described, and experiments using a coil wound with Bi-2223 multifilamentary tapes were carried out in liquid nitrogen to confirm the validity of the measurement method.

Published

2014

4. SP-0262 Limitations of current RBE models and their implication for clinical trial design

Author

N. Matsufuji

Subjects

medicine.medical_specialty, Oncology, business.industry, Clinical study design, Medicine, Radiology, Nuclear Medicine and imaging, Medical physics, Hematology, Current (fluid), business

Published

2019

5. Carbon-Ion Radiotherapy: Clinical Aspects and Related Dosimetry

Author

A. Fukumura, H. Tsujii, T. Kamada, M. Baba, H. Tsuji, H. Kato, S. Kato, S. Yamada, S. Yasuda, T. Yanagi, R. Hara, N. Yamamoto, J. Mizoe, K. Akahane, S. Fukuda, Y. Furusawa, Y. Iwata, T. Kanai, N. Kanematsu, A. Kitagawa, N. Matsufuji, S. Minohara, N. Miyahara, H. Mizuno, T. Murakami, K. Nishizawa, K. Noda, E. Takada, and S. Yonai

Subjects

Energy loss, medicine.medical_specialty, Biological efficiency, medicine.medical_treatment, Physics::Medical Physics, Dose distribution, Neoplasms, medicine, Humans, Dosimetry, Radiology, Nuclear Medicine and imaging, Medical physics, Carbon Radioisotopes, Carbon beam, Radiometry, Clinical Trials as Topic, Radiation, Radiological and Ultrasound Technology, business.industry, Public Health, Environmental and Occupational Health, General Medicine, Radiation therapy, Carbon Ion Radiotherapy, Physics::Accelerator Physics, Radiation protection, business, Nuclear medicine

Abstract

The features of relativistic carbon-ion beams are attractive from the viewpoint of radiotherapy. They exhibit not only a superior physical dose distribution but also an increase in biological efficiency with depth, because energy loss of the beams increases as they penetrate the body. This paper reviews clinical aspects of carbon-beam radiotherapy using the experience at the National Institute of Radiological Sciences. The paper also outlines the dosimetry related to carbon-beam radiotherapy, including absolute dosimetry of the carbon beam, neutron measurements and radiation protection measurements.

Published

2009

6. Objective assessment in digital images of skin erythema caused by radiotherapy

Author

H, Matsubara, N, Matsufuji, H, Tsuji, N, Yamamoto, K, Karasawa, M, Nakajima, W, Takahashi, and M, Karube

Subjects

Male, Lung Neoplasms, Erythema, Pigmentation, Humans, Female, Heavy Ion Radiotherapy, Middle Aged, Aged, Molecular Imaging, Skin

Abstract

Skin toxicity caused by radiotherapy has been visually classified into discrete grades. The present study proposes an objective and continuous assessment method of skin erythema in digital images taken under arbitrary lighting conditions, which is the case for most clinical environments. The purpose of this paper is to show the feasibility of the proposed method.Clinical data were gathered from six patients who received carbon beam therapy for lung cancer. Skin condition was recorded using an ordinary compact digital camera under unfixed lighting conditions; a laser Doppler flowmeter was used to measure blood flow in the skin. The photos and measurements were taken at 3 h, 30, and 90 days after irradiation. Images were decomposed into hemoglobin and melanin colors using independent component analysis. Pixel values in hemoglobin color images were compared with skin dose and skin blood flow. The uncertainty of the practical photographic method was also studied in nonclinical experiments.The clinical data showed good linearity between skin dose, skin blood flow, and pixel value in the hemoglobin color images; their correlation coefficients were larger than 0.7. It was deduced from the nonclinical that the uncertainty due to the proposed method with photography was 15%; such an uncertainty was not critical for assessment of skin erythema in practical use.Feasibility of the proposed method for assessment of skin erythema using digital images was demonstrated. The numerical relationship obtained helped to predict skin erythema by artificial processing of skin images. Although the proposed method using photographs taken under unfixed lighting conditions increased the uncertainty of skin information in the images, it was shown to be powerful for the assessment of skin conditions because of its flexibility and adaptability.

Published

2015

7. Overview summary of clinical heavier-ion progress in Japan

Author

N Matsufuji

Subjects

History, medicine.medical_specialty, business.industry, medicine, Carbon Ion Radiotherapy, 3d scanning, Medical physics, Heavy ion, business, Software technology, Computer Science Applications, Education

Abstract

Swift ion beams such as carbon has unique characteristics suitable for treating deep-seated tumours. In Japan, carbon-ion radiotherapy was started in 1994 at Heavy Ion Medical Accelerator in Chiba (HIMAC) at National Institute of Radiological Sciences and more than 10,000 patients have been treated by Aug. 2016. Clinical outcomes show superior efficacy of carbon ions even against radioresistant tumour while keeping the quality of life at high level, and also the usefulness of hypofractionated irradiation down to the completion of the course of lung-cancer treatment in 1 day. During the decades, the improvement of hardware and software technology such as 3D scanning technique, superconducting rotating gantry or biology model have been carried out aiming at further optimized ion-beam radiotherapy as well as reducing the cost of the facility. The developed technology has been transferred to the following facilities. As of 2016, 5 carbon ion radiotherapy facilities are in operation in Japan.

Published

2017

8. Light Ion Radiation Biology

Author

Y. Kase, Koichi Ando, and N. Matsufuji

Subjects

Neon, Cell killing, Chemistry, Radiochemistry, Carbon Ion Radiotherapy, chemistry.chemical_element, Lithium, Irradiation, Oxygen, Carbon, Ion

Abstract

Biological effects caused by light ion irradiation are described, including DNA damage, cell killing, and tissue and tumor response. Ion species include neutrons, protons, α particles, deuterons, helium, lead, carbon, neon, oxygen, lithium, and other ions, which have been reported since 1968 until 2011. Also included here are mathematical models currently used in clinical carbon ion radiotherapy.

Published

2014

9. Field size effect of radiation quality in carbon therapy using passive method

Author

H, Nose, Y, Kase, N, Matsufuji, and T, Kanai

Subjects

Radiotherapy, High-Energy, Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted, Humans, Scattering, Radiation, Radiotherapy, Conformal, Monte Carlo Method, Biophysical Phenomena, Carbon, Relative Biological Effectiveness

Abstract

The authors have investigated the dependency of radiation quality and absorbed dose on radiation field size in therapeutic carbon beams. The field size of the broad beam, formed using the passive technique, was controlled from 20 to 100 mm per side with a multileaf collimator. The absorbed dose and radiation quality on the beam center were evaluated at several depths in a water phantom using microdosimetric technique in experiments and Monte Carlo simulations. With an increase in the field size, the radiation quality was reduced, although the absorbed dose grew at the center of the field. This indicates that the dose and radiation quality at the center of the broad beam are influenced by particles from the off-center region via large-angle scattering and that such particles have relatively low radiation quality and mainly consist of fragment particles. Because such a tendency appeared to be more remarkable in the deeper region of the water phantom, it is likely that fragment particles that are born in a water phantom have a marked role in determining the field size effect.

Published

2009

10. New secondary beam course for medical use in HIMAC

Author

M. Kumada, A. Kitagawa, T. Murakami, M. Kanazawa, K. Noda, E. Takada, T. Kanai, Y. Ishikawa, S. Kouda, Takehiro Tomitani, Y. Sato, M. Torikoshi, Hiromi Tomura, Kiyomitsu Kawachi, M. Suda, H. Ogawa, T. Kato, N. Matsufuji, A. Higashi, S. Yamada, J. Yoshizawa, H. Tsubuku, and Y. Futami

Subjects

Radioactive ion beams, medicine.medical_specialty, Materials science, Medical treatment, medicine.diagnostic_test, Nuclear engineering, Physics::Physics Education, Computed tomography, Biomedical equipment, Medical services, Ion accelerators, medicine, Physics::Accelerator Physics, Medical physics, Nuclear Experiment, Beam (structure)

Abstract

A new beam course, a projectile fragment separator to provide radioactive beams, is under construction at HIMAC. A primary purpose of the new beam course is to study medical applications of radioactive beams. The specifications and status of the beam course and a preliminary result using carbon beams are summarized.

Published

2002

11. SU-E-T-26: A Study On the Influence of Photonuclear Reactions On the Biological Effectiveness of Therapeutic High Energy X-Ray Beam

Author

N Matsufuji, Y Suzuki, A Wakita, Toshiyuki Kohno, Satoshi Kodaira, Jun Itami, and K Yokoyama

Subjects

Physics, Photon, Monte Carlo method, X-ray detector, Dosimetry, General Medicine, Atomic physics, Spectral line, Linear particle accelerator, Beam (structure), Ion

Abstract

Purpose: Photons from a modern high-energy therapeutic linear accelerator used in X-ray radiotherapy causes photonuclear reactions in an accelerator or patient's body. The aim of this study is to evaluate the biological effectiveness including these particles by Microdosimetric Kinetic Model (MKM) based on microdosimetry. Methods: A linear accelerator operating at 15 MV was used. CR-39 was used to obtain LET spectra of secondary ions selectively, as CR-39 is regarded insensitive to photons. CR-39 was put on the central axis of the X-ray beam at depths of 0, 5 and 10 cm in plastic phantom at a source to detector distance of 100 cm. Pits formed by the traversal of ions were etched then analyzed to obtain restricted LET distribution. Frequency-mean and dose-mean lineal energy was evaluated from the relationship between the restricted LET and the lineal energy required to evaluate the biological effectiveness by MKM. The relationship was calculated by Monte Carlo simulations with GEANT4. Results: Restricted LET distributions of secondary particles showed broad distributions that decreases exponentially with increasing LET. Frequency-mean and dose-mean lineal energy were determined uniquely within the scope of the energies of secondary particles generated from photons of 15 MeV. The frequency-mean lineal energies at themore » depth of 0, 5 and 10 cm were 15.1, 16.0 and 19.7 keV/μm respectively, and the dose-mean lineal energies were 18.6, 20.5 and 19.6 keV/μm, respectively. RBE of secondary particles for HSG cell evaluated by MKM was about 2.0 at all depths, and RBE of all particles including photons was evaluated 1.0. Conclusion: We investigated the biological effectiveness of secondary particles by photonuclear reactions. The method to evaluate RBE by MKM was established with measurements and simulations. However, the influence of these secondary ions on RBE was found negligible in the entire biological effectiveness of the high-energy X-ray. This study has been supported by JSPS KAKENHI Grant Number 25861144.« less

Published

2014

12. [Development of a multi-layer ion chamber for measurement of depth dose distributions of heavy-ion therapeutic beam for individual patients]

Author

M, Shimbo, E, Urakabe, Y, Futami, K, Yusa, H, Yamashita, N, Matsufuji, T, Akagi, A, Higashi, and T, Kanai

Subjects

Radiotherapy, Humans, Heavy Ion Radiotherapy, Radiotherapy Dosage, Radiometry

Abstract

In heavy-ion radiotherapy, an accelerated beam is modified to realize a desired dose distribution in patients. The setup of the beam-modifying devices in the irradiation system is changed according to the patient, and it is important to check the depth dose distributions in the patient. In order to measure dose distributions realized by an irradiation system for heavy-ion radiotherapy, a multi-layer ionization chamber(MLIC) was developed. The MLIC consists of 64 ionization chambers, which are stacked mutually. The interval between each ionization chamber is about 4.1 mm water. There are signal and high voltage plates in the MILC, which are used as electrodes of the ionization chambers and phantom. Depth dose distribution from 5.09 mm to 261.92 mm water can be measured in about 30 seconds using this MLIC. Thus, it is possible to check beam quality in a short amount of time.

Published

2000

13. Present Status of HIMAC at NIRS

Author

E. Takada, Y. Futami, Fuminori Soga, T. Homma, N. Matsufuji, M. Kanazawa, T. Murakami, E. Urakabe, A. Kitagawa, Y. Sato, Kiyomitsu Kawachi, Koji Noda, M. Shimbo, Shinichi Minohara, N. Miyahara, M. Suda, M. Torikoshi, H. Yamashita, H. Koyama-Itou, M. Endo, T. Kanai, M. Muramatsu, S. Yamada, and M. Kumada

Subjects

Physics, medicine.medical_specialty, Ion accelerators, Nuclear engineering, Positron emitters, Verification system, medicine, Medical physics, Carbon beam, Accelerators and Storage Rings, Beam (structure)

Abstract

Since 1994 clinical trials have been performed successfully with carbon beam. To improve the clinical result further, new irradiation systems are under development such as a 3D-irradiation system and a verification system of range with positron emitter. There are also improvements on the accelerator performances. One is the wide range of ion species; the others are concerned with the machine devices and new beam monitors to get good machine operation. In this report we present current status of HIMAC.

Published

1999

14. Initial recombination in a parallel-plate ionization chamber exposed to heavy ions

Author

T, Kanai, M, Sudo, N, Matsufuji, and Y, Futami

Subjects

Radiotherapy, High-Energy, Air, Data Interpretation, Statistical, Iron, Dose-Response Relationship, Radiation, Heavy Ions, Linear Energy Transfer, Radiotherapy Dosage, Argon, Carbon Dioxide, Radiometry, Carbon, Mathematics

Abstract

For exact determination of absorbed dose in heavy-ion irradiation fields which are used in radiation therapy and biological experiments, ionization chambers have been characterized with defined heavy-ion beams and correction factors. The LET (linear energy transfer) dependence of columnar recombination in a parallel-plate ionization chamber has been examined. Using 135 MeV/u carbon and neon beams, the ion collection efficiency was measured for several gases (air, carbon dioxide, argon and tissue-equivalent gas). 95 MeV/u argon beams and 90 MeV/u iron beams were also used for measurements of columnar recombination in air. As expected by Jaffe theory, the inverse of the ratio of the ionization charge to the saturated ionization charge had a linear relationship with the inverse of the electric field strength in the region below 0.002 V(-1) cm. The gradient of the line increases as the LET of the heavy ions increases. A strong LET dependence of the gradient was observed in air and carbon dioxide. The LET dependence was not observed in tissue-equivalent gas, nitrogen or argon. The exact depth-dose distribution of the heavy-ion beam was obtained by this correction of the initial recombination effect for the collected ionization charge. The columnar recombination in air was analysed using Jaffe theory; the obtained parameter b (a track radius) should be in the range between 0.001 cm and 0.005 cm, whereas the value obtained by Jaffe is 0.00179 cm. The value of the parameter b should increase as the LET of the heavy-ion beam increases in order to reproduce the experimental values of the initial recombination.

Published

1998

15. Rejoining and misrejoining of radiation-induced chromatin breaks. IV Charged particles

Author

M. DURANTE, Y. FURUSAWA, K. GEORGE, G. GIALANELLA, O. GRECO, N. MATSUFUJI, PUGLIESE, MARIAGABRIELLA, T. C. YANG, GROSSI, GIANFRANCO, Durante, M., Furusawa, Y., George, K., Gialanella, G., Greco, O., Grossi, Gianfranco, Matsufuji, N., Pugliese, Mariagabriella, and Yang, T. C.

Published

1998

16. Characterisation of an ultra-miniature counter for microdosimetric measurements in a therapeutic 400 MeV/A carbon beam

Author

Kiyoshi Shizuma, M. Ishikawa, Masaharu Hoshi, Tatsuaki Kanai, Hiroshi Yamaguchi, Satoru Endo, Shuzo Uehara, Masashi Takada, N Matsufuji, and Yoshihiko Onizuka

Subjects

Range (particle radiation), Miniaturization, Radiation, Materials science, Radiological and Ultrasound Technology, Public Health, Environmental and Occupational Health, Physics::Optics, chemistry.chemical_element, Proportional counter, Radiotherapy Dosage, Bragg peak, General Medicine, Sensitivity and Specificity, Spectral line, chemistry, Aluminium, Calibration, Scintillation counter, Radiology, Nuclear Medicine and imaging, Carbon Radioisotopes, Atomic physics, Radiometry, Carbon

Abstract

Single event spectra of a clinical carbon beam have been measured by an ultra-miniature tissure-equivalent proportional counter (UMC). In order to cover the energy range of the Bragg peak, the incident energy of the carbon beam was degraded by aluminium plates. Single event spectra for carbon-events incident to the UMC were analysed and selected at several carbon energies using thin scintillation counters. It was found that the dose weighted lineal energy distributions have a doublet peak structure due to incident carbon beam and fragment contributions.

17. Modelling the Biological Beamline at HIMAC using Geant4.

Author

D Bolst, L T Tran, S Guatelli, N Matsufuji, and A B Rosenfeld

Published

2019

18. 3D sensitive volume microdosimeter with improved tissue equivalency: charge collection study and its application in 12C ion therapy.

Author

B James, L T Tran, D Bolst, D Prokopovich, M Reinhard, M Lerch, M Petasecca, S Guatelli, M Povoli, A Kok, N Matsufuji, M Jackson, and A Rosenfeld

Published

2019

19. The FLUKA Monte Carlo code coupled with the NIRS approach for clinical dose calculations in carbon ion therapy.

Author

G Magro, T J Dahle, S Molinelli, M Ciocca, P Fossati, A Ferrari, T Inaniwa, N Matsufuji, K S Ytre-Hauge, and A Mairani

Subjects

RADIOTHERAPY treatment planning, MONTE Carlo method, ONCOLOGY

Abstract

Particle therapy facilities often require Monte Carlo (MC) simulations to overcome intrinsic limitations of analytical treatment planning systems (TPS) related to the description of the mixed radiation field and beam interaction with tissue inhomogeneities. Some of these uncertainties may affect the computation of effective dose distributions; therefore, particle therapy dedicated MC codes should provide both absorbed and biological doses. Two biophysical models are currently applied clinically in particle therapy: the local effect model (LEM) and the microdosimetric kinetic model (MKM). In this paper, we describe the coupling of the NIRS (National Institute for Radiological Sciences, Japan) clinical dose to the FLUKA MC code. We moved from the implementation of the model itself to its application in clinical cases, according to the NIRS approach, where a scaling factor is introduced to rescale the (carbon-equivalent) biological dose to a clinical dose level. A high level of agreement was found with published data by exploring a range of values for the MKM input parameters, while some differences were registered in forward recalculations of NIRS patient plans, mainly attributable to differences with the analytical TPS dose engine (taken as reference) in describing the mixed radiation field (lateral spread and fragmentation). We presented a tool which is being used at the Italian National Center for Oncological Hadrontherapy to support the comparison study between the NIRS clinical dose level and the LEM dose specification. [ABSTRACT FROM AUTHOR]

Published

2017

20. New silicon microdosimetry probes for RBE and biological dose studies using stationary and movable targets in 12C ion therapy.

Author

L Chartier, L T Tran, D Bolst, A Pogossov, S Guatelli, M Petasecca, M Lerch, D Prokopovich, M Reinhard, V Perevertaylo, M Jackson, N Matsufuji, and A B Rosenfeld

Published

2017

21. Adaptation of the microdosimetric kinetic model to hypoxia.

Author

C Bopp, R Hirayama, T Inaniwa, A Kitagawa, N Matsufuji, and K Noda

Subjects

HYPOXEMIA, ION beams, LINEAR energy transfer, TUMOR prevention, OXYGENATION (Chemistry), THERAPEUTICS

Abstract

Ion beams present a potential advantage in terms of treatment of lesions with hypoxic regions. In order to use this potential, it is important to accurately model the cell survival of oxic as well as hypoxic cells. In this work, an adaptation of the microdosimetric kinetic (MK) model making it possible to account for cell hypoxia is presented. The adaptation relies on the modification of damage quantity (double strand breaks and more complex lesions) due to the radiation. Model parameters such as domain size and nucleus size are then adapted through a fitting procedure. We applied this approach to two cell lines, HSG and V79 for helium, carbon and neon ions. A similar behaviour of the parameters was found for the two cell lines, namely a reduction of the domain size and an increase in the sensitive nuclear volume of hypoxic cells compared to those of oxic cells. In terms of oxygen enhancement ratio (OER), the experimental data behaviour can be reproduced, including dependence on particle type at the same linear energy transfer (LET). Errors on the cell survival prediction are of the same order of magnitude than for the original MK model. Our adaptation makes it possible to account for hypoxia without modelling the OER as a function of the LET of the particles, but directly accounting for hypoxic cell survival data. [ABSTRACT FROM AUTHOR]

Published

2016

22. Synchrotron-based infrared microspectroscopy unveils the biomolecular response of healthy and tumour cell lines to neon minibeam radiation therapy.

Author

González-Vegas R, Seksek O, Bertho A, Bergs J, Hirayama R, Inaniwa T, Matsufuji N, Shimokawa T, Prezado Y, Yousef I, and Martínez-Rovira I

Subjects

Humans, Spectroscopy, Fourier Transform Infrared methods, Cell Line, Tumor, Animals, Neon chemistry, Mice, Principal Component Analysis, Heavy Ion Radiotherapy methods, Synchrotrons

Abstract

Radioresistant tumours remain complex to manage with current radiotherapy (RT) techniques. Heavy ion beams were proposed for their treatment given their advantageous radiobiological properties. However, previous studies with patients resulted in serious adverse effects in the surrounding healthy tissues. Heavy ion RT could therefore benefit from the tissue-sparing effects of minibeam radiation therapy (MBRT). To investigate the potential of this combination, here we assessed the biochemical response to neon MBRT (NeMBRT) through synchrotron-based Fourier transform infrared microspectroscopy (SR-FTIRM). Healthy (BJ) and tumour (B16-F10) cell lines were subjected to seamless (broad beam) neon RT (NeBB) and NeMBRT at HIMAC. SR-FTIRM measurements were conducted at the MIRAS beamline of ALBA Synchrotron. Principal component analysis (PCA) permitted to assess the biochemical effects after the irradiations and 24 hours post-irradiation for the different RT modalities and doses. For the healthy cells, NeMBRT resulted in the most dissimilar spectral signatures from non-irradiated cells early after irradiations, mainly due to protein conformational modifications. Nevertheless, most of the damage appeared to recover one day post-RT; conversely, protein- and nucleic acid-related IR bands were strongly affected by NeBB 24 hours after treatment, suggesting superior oxidative damage and nucleic acid degradation. Tumour cells appeared to be less sensitive to NeBB than to NeMBRT shortly after RT. Still, after one day, both NeBB and the high-dose NeMBRT regions yielded important spectral modifications, suggestive of cell death processes, protein oxidation or oxidative stress. Lipid-associated spectral changes, especially due to the NeBB and NeMBRT peak groups for the tumour cell line, were consistent with reactive oxygen species attacks.

Published

2025

23. Neutron Capture Enhances Dose and Reduces Cancer Cell Viability in and out of Beam During Helium and Carbon Ion Therapy.

Author

Howell N, Middleton RJ, Sierro F, Fraser BH, Wyatt NA, Chacon A, Bambery KR, Livio E, Dobie C, Bevitt JJ, Davies J, Dosseto A, Franklin DR, Garbe U, Guatelli S, Hirayama R, Matsufuji N, Mohammadi A, Mutimer K, Rendina LM, Rosenfeld AB, and Safavi-Naeini M

Subjects

Humans, Cell Line, Tumor, Heavy Ion Radiotherapy methods, Neutron Capture Therapy methods, Neutrons therapeutic use, Radiotherapy Dosage, Boron Neutron Capture Therapy methods, Boron therapeutic use, Polymethyl Methacrylate, Isotopes, Helium therapeutic use, Glioblastoma radiotherapy, Glioblastoma pathology, Cell Survival radiation effects, Phantoms, Imaging, Carbon therapeutic use

Abstract

Purpose: Neutron capture enhanced particle therapy (NCEPT) is a proposed augmentation of charged particle therapy that exploits thermal neutrons generated internally, within the treatment volume via nuclear fragmentation, to deliver a biochemically targeted radiation dose to cancer cells. This work is the first experimental demonstration of NCEPT, performed using both carbon and helium ion beams with 2 different targeted neutron capture agents (NCAs)., Methods and Materials: Human glioblastoma cells (T98G) were irradiated by carbon and helium ion beams in the presence of NCAs [ 10 B]-BPA and [ 157 Gd]-DOTA-TPP. Cells were positioned within a polymethyl methacrylate phantom either laterally adjacent to or within a 100 × 100 × 60 mm spread out Bragg peak (SOBP). The effect of NCAs and location relative to the SOBP on the cells was measured by cell growth and survival assays in 6 independent experiments. Neutron fluence within the phantom was characterized by quantifying the neutron activation of gold foil., Results: Cells placed inside the treatment volume reached 10% survival by 2 Gy of carbon or 2 to 3 Gy of helium in the presence of NCAs compared with 5 Gy of carbon and 7 Gy of helium with no NCA. Cells placed adjacent to the treatment volume showed a dose-dependent decrease in cell growth when treated with NCAs, reaching 10% survival by 6 Gy of carbon or helium (to the treatment volume), compared with no detectable effect on cells without NCA. The mean thermal neutron fluence at the center of the SOBP was approximately 2.2 × 10 9 n/cm 2 /Gy (relative biological effectiveness) for the carbon beam and 5.8 × 10 9 n/cm 2 /Gy (relative biological effectiveness) for the helium beam and gradually decreased in all directions., Conclusions: The addition of NCAs to cancer cells during carbon and helium beam irradiation has a measurable effect on cell survival and growth in vitro. Through the capture of internally generated neutrons, NCEPT introduces the concept of a biochemically targeted radiation dose to charged particle therapy. NCEPT enables the established pharmaceuticals and concepts of neutron capture therapy to be applied to a wider range of deeply situated and diffuse tumors, by targeting this dose to microinfiltrates and cells outside of defined treatment regions. These results also demonstrate the potential for NCEPT to provide an increased dose to tumor tissue within the treatment volume, with a reduction in radiation doses to off-target tissue., (Crown Copyright © 2024. Published by Elsevier Inc. All rights reserved.)

Published

2024

24. Stopping-power ratio of body tissues with updated effective energies and elemental I values for treatment planning of proton therapy and ion beam therapy with helium, carbon, oxygen, and neon ions.

Author

Inaniwa T, Weichert E, Masuda T, Tanaka S, Matsufuji N, and Kanematsu N

Subjects

Humans, Helium therapeutic use, Neon therapeutic use, Oxygen therapeutic use, Carbon therapeutic use, Radiotherapy Planning, Computer-Assisted, Water, Proton Therapy

Abstract

The stopping-power ratio (SPR) of body tissues relative to water depends on the particle energy and mean excitation energy (I value) of the tissues. Effective energies to minimize the range error in proton therapy and ion beam therapy with helium, carbon, oxygen, and neon ions and elemental I values have been updated in recent studies. We investigated the effects of these updates on SPR estimation for computed tomography-based treatment planning. The updates led to an increase of up to 0.5% in the SPRs of soft tissues, whereas they led to a decrease of up to 1.9% in the SPRs of bone tissues compared with the current clinical settings. For 44 proton beams planned for 15 randomly sampled patients, the mean water-equivalent target depth change was - 0.2 mm with a standard deviation of 0.2 mm. The maximum change was - 0.6 mm, which we consider to be insignificant in clinical practice., (© 2023. The Author(s), under exclusive licence to Japanese Society of Radiological Technology and Japan Society of Medical Physics.)

Published

2023

25. In Vivo Dosimetry in the Urethra During Prostate Carbon Ion Radiotherapy.

Author

Matsumoto S, Matsufuji N, Koba Y, and Tsuji H

Subjects

Male, Humans, Urethra, Prostate, Radiometry methods, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted methods, Prostatic Neoplasms radiotherapy, Heavy Ion Radiotherapy, Brachytherapy methods

Abstract

Background/aim: In vivo dosimetry can prevent dose delivery errors by directly measuring the dose of radiation administered to a patient. However, a method for in vivo dosimetry during carbon ion radiotherapy (CIRT) has not been established. Therefore, we investigated data from in vivo dosimetry of the urethra during CIRT for prostate cancer using small spherical diode dosimeters (SSDDs)., Patients and Methods: This study included five patients enrolled in a clinical trial (jRCT identifier: jRCTs032190180) on which the use of four-fraction CIRT for prostate cancer was examined. The urethral dose during CIRT for prostate cancer was measured using the SSDDs inserted into the ureteral catheter. The relative error between the in vivo and calculated doses obtained using the Xio-N treatment planning system was determined. Additionally, a dose-response stability test for the in vivo dosimeter was performed under clinical conditions., Results: The relative error between the in vivo and calculated urethral doses ranged from 6 to 12%. The dose-response stability under clinical conditions of the measured dose was ≤1%. Therefore, an error >1% would be due to an interfractional patient setup error in the large dose gradient in the urethra., Conclusion: The usefulness of in vivo dosimetry using SSDDs in CIRT and SSDDs' potential for detecting dose delivery errors during CIRT is herein highlighted., (Copyright © 2023 International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved.)

Published

2023

26. The clinical relative biological effectiveness and prostate-specific antigen kinetics of carbon-ion radiotherapy in low-risk prostate cancer.

Author

Kang YM, Ishikawa H, Inaniwa T, Iwai Y, Matsufuji N, Kasuya G, Okonogi N, Liu YM, Chao Y, Wakatsuki M, Tsujii H, and Tsuji H

Subjects

Male, Humans, Aged, Retrospective Studies, Relative Biological Effectiveness, Carbon, Prostate-Specific Antigen, Prostatic Neoplasms radiotherapy, Prostatic Neoplasms pathology

Abstract

Background: To evaluate the clinical relative biological effectiveness (RBE) of carbon-ion radiotherapy (C-ion RT) for prostate cancer., Methods: The records of 262 patients with low-risk prostate cancer (median age, 65 [47-80] years) treated with C-ion RT at QST Hospital, National Institutes for Quantum Science and Technology in Japan during 2000-2018 were reviewed retrospectively. Four different protocol outcomes and prostate-specific antigen (PSA) responses were evaluated. The median follow-up was 8.4 years. The Kaplan-Meier method was used to estimate the biochemical or clinical failure-free rate (BCFFR). Clinical RBE was calculated using the tumor control probability model., Results: The 5-, 7-, and 10-year BCFFRs were 91.7%, 83.8%, and 73.2%, respectively. The 10-year BCFFRs of patients who received C-ion RT at 66 Gy (RBE) in 20 fractions, 63 Gy (RBE) in 20 fractions, and 57.6 Gy (RBE) in 16 fractions were 81.4%, 70.9%, and 68.9%, respectively. The PSA level and density during follow-up were better in the patients treated with the lower fraction size. A higher PSA nadir and shorter time to PSA nadir were risk factors for biochemical or clinical failure by multivariate Cox regression. The tumor control probability analysis showed that the estimated clinical RBE values to achieve an 80% BCFFR at 10 years for 20, 16, and 12 fractions were 2.19 (2.18-2.24), 2.16 (2.14-2.23), and 2.12 (2.09-2.21), respectively., Conclusions: Using clinical data from low-risk prostate cancer patients, we showed the clinical RBE of C-ion RT decreased with increasing dose per fraction., (© 2022 The Authors. Cancer Medicine published by John Wiley & Sons Ltd.)

Published

2023

27. Dose- and LET-dependent changes in mouse skin contracture up to a year after either single dose or fractionated doses of carbon ion or gamma rays.

Author

Ando K, Yoshida Y, Hirayama R, Koike S, and Matsufuji N

Subjects

Animals, Carbon, Cell Survival radiation effects, Dose-Response Relationship, Radiation, Gamma Rays, Ions, Mice, Mice, Inbred C3H, Relative Biological Effectiveness, Contracture, Linear Energy Transfer

Abstract

Time dependence of relative biological effectiveness (RBE) of carbon ions for skin damage was investigated to answer the question of whether the flat distribution of biological doses within a Spread-Out Bragg peak (SOBP) which is designed based on in vitro cell kill could also be flat for in vivo late responding tissue. Two spots of Indian ink intracutaneously injected into the legs of C3H mice were measured by calipers. An equieffective dose to produce 30% skin contraction was calculated from a dose-response curve and used to calculate the RBE of carbon ion beams. We discovered skin contraction progressed after irradiation and then reached a stable/slow progression phase. Equieffective doses decreased with time and the decrease was most prominent for gamma rays and least prominent for 100 keV/μm carbon ions. Survival parameter of alpha but not beta in the linear-quadratic model is closely related to the RBE of carbon ions. Biological doses within the SOBP increased with time but their distribution was still flat up to 1 year after irradiation. The outcomes of skin contraction studies suggest that (i) despite the higher RBE for skin contracture after carbon ions compared to gamma rays, gamma rays can result in a more severe late effect of skin contracture. This is due to the carbon effect saturating at a lower dose than gamma rays, and (ii) the biological dose distribution throughout the SOBP remains approximately the same even one year after exposure., (© The Author(s) 2022. Published by Oxford University Press on behalf of The Japanese Radiation Research Society and Japanese Society for Radiation Oncology.)

Published

2022

28. A Potential Renewed Use of Very Heavy Ions for Therapy: Neon Minibeam Radiation Therapy.

Author

Prezado Y, Hirayama R, Matsufuji N, Inaniwa T, Martínez-Rovira I, Seksek O, Bertho A, Koike S, Labiod D, Pouzoulet F, Polledo L, Warfving N, Liens A, Bergs J, and Shimokawa T

Abstract

(1) Background: among all types of radiation, very heavy ions, such as Neon (Ne) or Argon (Ar), are the optimum candidates for hypoxic tumor treatments due to their reduced oxygen enhancement effect. However, their pioneering clinical use in the 1970s was halted due to severe side effects. The aim of this work was to provide a first proof that the combination of very heavy ions with minibeam radiation therapy leads to a minimization of toxicities and, thus, opening the door for a renewed use of heavy ions for therapy; (2) Methods: mouse legs were irradiated with either Ne MBRT or Ne broad beams at the same average dose. Skin toxicity was scored for a period of four weeks. Histopathology evaluations were carried out at the end of the study; (3) Results: a significant difference in toxicity was observed between the two irradiated groups. While severe da-mage, including necrosis, was observed in the broad beam group, only light to mild erythema was present in the MBRT group; (4) Conclusion: Ne MBRT is significantly better tolerated than conventional broad beam irradiations.

Published

2021

29. Development and characterization of optical readout well-type glass gas electron multiplier for dose imaging in clinical carbon beams.

Author

Fujiwara T, Koba Y, Mitsuya Y, Nakamura R, Tatsumoto R, Kawahara S, Maehata K, Yamaguchi H, Chang W, Matsufuji N, and Takahashi H

Subjects

Gases, Linear Energy Transfer, Radiometry, Carbon, Electrons

Abstract

The use of carbon ion beams in cancer therapy (also known as hadron therapy) is steadily growing worldwide; therefore, the demand for more efficient dosimetry systems is also increasing because daily quality assurance (QA) measurements of hadron radiotherapy is one of the most complex and time consuming tasks. The aim of this study is to develop a two-dimensional dosimetry system that offers high spatial resolution, a large field of view, quick data response, and a linear dose-response relationship. We demonstrate the dose imaging performance of a novel digital dose imager using carbon ion beams for hadron therapy. The dose imager is based on a newly-developed gaseous detector, a well-type glass gas electron multiplier. The imager is successfully operated in a hadron therapy facility with clinical intensity beams for radiotherapy. It features a high spatial resolution of less than 1 mm and an almost linear dose-response relationship with no saturation and very low linear-energy-transfer dependence. Experimental results show that the dose imager has the potential to improve dosimetry accuracy for daily QA., (Copyright © 2021 Associazione Italiana di Fisica Medica. Published by Elsevier Ltd. All rights reserved.)

Published

2021

30. Dose-averaged linear energy transfer per se does not correlate with late rectal complications in carbon-ion radiotherapy.

Author

Okonogi N, Matsumoto S, Fukahori M, Furuichi W, Inaniwa T, Matsufuji N, Imai R, Yamada S, Kanematsu N, and Tsuji H

Subjects

Carbon, Humans, Relative Biological Effectiveness, Retrospective Studies, Linear Energy Transfer, Proton Therapy

Abstract

Background and Purpose: Several studies have focused on increasing the linear energy transfer (LET) within tumours to achieve higher biological effects in carbon-ion radiotherapy (C-ion RT). However, it remains unclear whether LET affects late complications. We assessed whether physical dose and LET distribution can be specific factors for late rectal complications in C-ion RT., Materials and Methods: Overall, 134 patients with uterine carcinomas were registered and retrospectively analysed. Of 134 patients, 132 who were followed up for >6 months were enrolled. The correlations between the relative biological effectiveness (RBE)-weighted dose based on the Kanai model (the ostensible "clinical dose"), dose-averaged LET (LETd), or physical dose and rectal complications were evaluated. Rectal complications were graded according to the Radiation Therapy Oncology Group/European Organization for Research and Treatment of Cancer criteria., Results: Nine patients developed grade 3 or 4 late rectal complications. Linear regression analysis found that D 2cc in clinical dose was the sole risk factor for ≥grade 3 late rectal complications (p = 0.012). The receiver operating characteristic analysis found that D 2cc of 60.2 Gy (RBE) was a suitable cut-off value for predicting ≥grade 3 late rectal complications. Among 35 patients whose rectal D 2cc was ≥60.2 Gy (RBE), no correlations were found between severe rectal toxicities and LETd alone or physical dose per se., Conclusion: We demonstrated that severe rectal toxicities were related to the rectal D 2cc of the clinical dose in C-ion RT. However, no correlations were found between severe rectal toxicities and LETd alone or physical dose per se., (Copyright © 2020 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2020

31. Unresectable Chondrosarcomas Treated With Carbon Ion Radiotherapy: Relationship Between Dose-averaged Linear Energy Transfer and Local Recurrence.

Author

Matsumoto S, Lee SH, Imai R, Inaniwa T, Matsufuji N, Fukahori M, Kohno R, Yonai S, Okonogi N, Yamada S, and Kanematsu N

Subjects

Algorithms, Chondrosarcoma pathology, Female, Humans, Linear Energy Transfer, Male, Monte Carlo Method, Neoplasm Recurrence, Local pathology, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Tumor Burden, Chondrosarcoma radiotherapy, Heavy Ion Radiotherapy, Neoplasm Recurrence, Local radiotherapy, Radiation Dosage

Abstract

Background/aim: The local control rate of chondrosarcomas treated with carbon-ion radiotherapy (CIRT) worsens as tumour size increases, possibly because of the intra-tumoural linear energy transfer (LET) distribution. This study aimed to evaluate the relationship between local recurrence and intra-tumoural LET distribution in chondrosarcomas treated with CIRT., Patients and Methods: Thirty patients treated with CIRT for grade 2 chondrosarcoma were included. Dose-averaged LET (LET d ) distribution was calculated by the treatment planning system, and the relationship between LET d distribution in the planning tumour volume (PTV) and local control was evaluated., Results: The mean LET d value in PTV was similar between cases with and without recurrence. Recurrence was not observed in cases where the effective minimum LET d value exceeded 40 keV/μm., Conclusion: LET d distribution in PTV is associated with local control in chondrosarcomas and patients treated with ion beams of higher LET d may have an improved local control rate for unresectable chondrosarcomas., (Copyright© 2020, International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved.)

Published

2020

32. Validation of Geant4 for silicon microdosimetry in heavy ion therapy.

Author

Bolst D, Guatelli S, Tran LT, Chartier L, Davis J, Biasi G, Prokopovich DA, Pogossov A, Reinhard MI, Petasecca M, Lerch MLF, Matsufuji N, Povoli M, Summanwar A, Kok A, Jackson M, and Rosenfeld AB

Subjects

Kinetics, Models, Biological, Relative Biological Effectiveness, Heavy Ion Radiotherapy, Monte Carlo Method, Radiometry methods, Silicon

Abstract

Microdosimetry is a particularly powerful method to estimate the relative biological effectiveness (RBE) of any mixed radiation field. This is particularly convenient for therapeutic heavy ion therapy (HIT) beams, referring to ions larger than protons, where the RBE of the beam can vary significantly along the Bragg curve. Additionally, due to the sharp dose gradients at the end of the Bragg peak (BP), or spread out BP, to make accurate measurements and estimations of the biological properties of a beam a high spatial resolution is required, less than a millimetre. This requirement makes silicon microdosimetry particularly attractive due to the thicknesses of the sensitive volumes commonly being  ∼10 [Formula: see text]m or less. Monte Carlo (MC) codes are widely used to study the complex mixed HIT radiation field as well as to model the response of novel microdosimeter detectors when irradiated with HIT beams. Therefore it is essential to validate MC codes against experimental measurements. This work compares measurements performed with a silicon microdosimeter in mono-energetic [Formula: see text], [Formula: see text] and [Formula: see text] ion beams of therapeutic energies, against simulation results calculated with the Geant4 toolkit. Experimental and simulation results were compared in terms of microdosimetric spectra (dose lineal energy, [Formula: see text]), the dose mean lineal energy, y  D and the RBE 10 , as estimated by the microdosimetric kinetic model (MKM). Overall Geant4 showed reasonable agreement with experimental measurements. Before the distal edge of the BP, simulation and experiment agreed within  ∼10% for y  D and  ∼2% for RBE 10 . Downstream of the BP less agreement was observed between simulation and experiment, particularly for the [Formula: see text] and [Formula: see text] beams. Simulation results downstream of the BP had lower values of y  D and RBE 10 compared to the experiment due to a higher contribution from lighter fragments compared to heavier fragments.

Published

2020

33. Influence of dose-averaged linear energy transfer on tumour control after carbon-ion radiation therapy for pancreatic cancer.

Author

Hagiwara Y, Bhattacharyya T, Matsufuji N, Isozaki Y, Takiyama H, Nemoto K, Tsuji H, and Yamada S

Abstract

Background and Purpose: High linear energy transfer (LET) radiation carbon-ion radiotherapy (C-ion RT) is one of the most promising modalities for treating unresectable primary pancreatic cancers. However, how LET contributes to a therapeutic effect is not clear. To assess whether there is an enhanced effect of high LET radiation on tumour control, we aimed to determine the impact of dose-averaged LET on local control (LC) of primary pancreatic tumours., Materials and Methods: A retrospective analysis of 18 patients with primary pancreatic carcinomas treated with definitive C-ion RT with concurrent chemotherapy in 2013 was conducted. The dose of irradiation was 55.2 Gy (RBE). The relationship between dose-averaged LET and LC of primary tumours was evaluated., Results: All patients had histologically confirmed adenocarcinoma. The median follow-up duration was 22 months. The actuarial LC and overall survival (OS) at 18 months were 62.5% and 70.1%, respectively. There were no cases of grade ≥3 late toxicities observed. Local recurrences developed in four patients (22%), all of which were infield central recurrences. Although there were no significant differences in gross tumour volume (GTV) dose coverage, patients with higher minimum dose-averaged LET (LETmin) values within the GTV had better LC (dose-averaged LETmin ≥44 keV/microm; 18-months LC 100.0% vs 34.3%; p = 0.0366)., Conclusion: Dose-averaged LETmin within the GTV was significantly associated with LC of primary pancreatic cancers. Our data suggest that outcomes for patients with unresectable primary pancreatic cancers receiving C-ion RT can be improved by modulating the dose-averaged LET within the GTV., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2019 The Authors.)

Published

2019

34. ESTIMATION OF RBE VALUES FOR CARBON-ION BEAMS IN THE WIDE DOSE RANGE USING MULTICELLULAR SPHEROIDS.

Author

Matsumoto Y, Furusawa Y, Aoki-Nakano M, Matsufuji N, Hirayama R, Kanai T, Ando K, and Sakurai H

Subjects

Argon chemistry, Carbon chemistry, Cell Survival radiation effects, Dose-Response Relationship, Radiation, Heavy Ions, Humans, Linear Energy Transfer, Software, Tumor Cells, Cultured, X-Rays, Heavy Ion Radiotherapy, Melanoma radiotherapy, Relative Biological Effectiveness, Spheroids, Cellular radiation effects

Abstract

Hypofractionated carbon-ion therapy has been applied to treatment of several tumours. In this case, relative biological effectiveness (RBE) at high dose region must be considered, however, the RBE calculated physically has been not verified biologically. In this study, spheroid technique was adopted to estimate RBE in wide dose range. Cells were irradiated with X-rays and heavy-ions with LET of 13, 35, 100 and 300 keV/μm with monolayer and spheroid condition. Surviving fractions in wide dose range (0-15 Gy) were obtained to combined monolayer with spheroid survival data. The linear-quadratic and multi-target single-hit equation fitted well in survival data at low dose, and high dose region, respectively. A multi-process equation showed best fitting for survival data in wide dose range. RBE values of heavy-ions could be estimated by combination of monolayer and spheroid data. The values converged at 1.1-1.4 and varied by LET values at high and low dose region, respectively., (© The Author(s) 2019. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2019

35. INVESTIGATING VARIABLE RBE IN A 12C MINIBEAM FIELD WITH MICRODOSIMETRY AND GEANT4.

Author

Debrot E, Bolst D, James B, Tran L, Guatelli S, Petasecca M, Prokopovich DA, Reinhard M, Matsufuji N, Jackson M, Lerch M, and Rosenfeld AB

Subjects

Computer Simulation, Heavy Ion Radiotherapy, Linear Energy Transfer, Silicon, Microtechnology methods, Radiometry methods, Relative Biological Effectiveness

Abstract

An experimental and simulation-based study was performed on a 12C ion minibeam radiation therapy (MBRT) field produced with a clinical broad beam and a brass multi-slit collimator (MSC). Silicon-on-insulator (SOI) microdosimeters developed at the Centre for Medical Radiation Physics (CMRP) with micron sized sensitive volumes were used to measure the microdosimetric spectra at varying positions throughout the MBRT field and the corresponding dose-mean lineal energies and RBE for 10% cell survival (RBE10) were calculated using the modified Microdosimetric Kinetic Model (MKM). An increase in the average RBE10 of ∼30% and 10% was observed in the plateau region compared to broad beam for experimental and simulation values, respectively. The experimental collimator misalignment was determined to be 0.7° by comparison between measured and simulated microdosimetric spectra at varying collimator angles. The simulated dose-mean lineal energies in the valley region between minibeams were found to be higher on average than in the minibeams due to higher LET particles being produced in these regions from the MSC. This work presents the first experimental microdosimetry measurements and characterisation of the local biological effectiveness in a MBRT field., (© The Author(s) 2019. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2019

36. The radiobiological effects of He, C and Ne ions as a function of LET on various glioblastoma cell lines.

Author

Chew MT, Bradley DA, Suzuki M, Matsufuji N, Murakami T, Jones B, and Nisbet A

Subjects

Cell Line, Tumor, Cell Survival drug effects, Cell Survival radiation effects, Humans, Radiobiology, Carbon pharmacology, Glioblastoma radiotherapy, Heavy Ions, Helium pharmacology, Linear Energy Transfer radiation effects, Neon pharmacology

Abstract

The effects of the charged ion species 4He, 12C and 20Ne on glioblastoma multiforme (GBM) T98G, U87 and LN18 cell lines were compared with the effects of 200 kVp X-rays (1.7 keV/μm). These cell lines have different genetic profiles. Individual GBM relative biological effectiveness (RBE) was estimated in two ways: the RBE10 at 10% survival fraction and the RBE2Gy after 2 Gy doses. The linear quadratic model radiosensitivity parameters α and β and the α/β ratio of each ion type were determined as a function of LET. Mono-energetic 4He, 12C and 20Ne ions were generated by the Heavy Ion Medical Accelerator at the National Institute of Radiological Sciences in Chiba, Japan. Colony-formation assays were used to evaluate the survival fractions. The LET of the various ions used ranged from 2.3 to 100 keV/μm (covering the depth-dose plateau region to clinically relevant LET at the Bragg peak). For U87 and LN18, the RBE10 increased with LET and peaked at 85 keV/μm, whereas T98G peaked at 100 keV/μm. All three GBM α parameters peaked at 100 keV/μm. There is a statistically significant difference between the three GBM RBE10 values, except at 100 keV/μm (P < 0.01), and a statistically significant difference between the α values of the GBM cell lines, except at 85 and 100 keV/μm. The biological response varied depending on the GBM cell lines and on the ions used., (© The Author(s) 2019. Published by Oxford University Press on behalf of The Japan Radiation Research Society and Japanese Society for Radiation Oncology.)

Published

2019

37. [Estimation of linear energy transfer distribution for broad-beam carbon-ion raiotherapy at the National Institute of Radiological Sciences, Japan].

Author

Kanematsu N, Matsufuji N, and Inaniwa T

Subjects

Carbon, Ions, Japan, Heavy Ion Radiotherapy, Linear Energy Transfer

Published

2019

38. Single fraction carbon ion radiotherapy for colorectal cancer liver metastasis: A dose escalation study.

Author

Makishima H, Yasuda S, Isozaki Y, Kasuya G, Okada N, Miyazaki M, Mohamad O, Matsufuji N, Yamada S, Tsuji H, and Kamada T

Subjects

Aged, Aged, 80 and over, Colorectal Neoplasms pathology, Dose-Response Relationship, Radiation, Female, Heavy Ion Radiotherapy adverse effects, Humans, Kaplan-Meier Estimate, Liver Neoplasms secondary, Male, Middle Aged, Neoplasm Recurrence, Local, Prognosis, Colorectal Neoplasms radiotherapy, Heavy Ion Radiotherapy methods, Liver Neoplasms radiotherapy, Radiotherapy Dosage

Abstract

Prognosis is usually grim for those with liver metastasis from colorectal cancer (CRC) who cannot receive resection. Radiation therapy can be an option for those unsuitable for resection, with carbon ion radiotherapy (CIRT) being more effective and less toxic than X-ray due to its physio-biological characteristics. The objective of this study is to identify the optimal dose of single fraction CIRT for colorectal cancer liver metastasis. Thirty-one patients with liver metastasis from CRC were enrolled in the present study. Twenty-nine patients received a single-fraction CIRT, escalating the dose from 36 Gy (RBE) in 5% to 10% increments until unacceptable incidence of dose-limiting toxicity was observed. Dose-limiting toxicity was defined as grade ≥3 acute toxicity attributed to radiotherapy. The prescribed doses were as follows: 36 Gy (RBE) (3 cases), 40 Gy (2 cases), 44 Gy (4 cases), 46 Gy (6 cases), 48 Gy (3 cases), 53 Gy (8 cases) and 58 Gy (3 cases). Dose-limiting toxicity was not observed, but late grade 3 liver toxicity due to biliary obstruction was observed in 2 patients at 53 Gy (RBE). Both cases had lesions close to the hepatic portal region, and, therefore, the dose was escalated to 58 Gy (RBE), limited to peripheral lesions. The 3-year actuarial overall survival rate of all 29 patients was 78%, and the median survival time was 65 months. Local control improved significantly at ≥53 Gy (RBE), with a 3-year actuarial local control rate of 82%, compared to 28% in lower doses. Treatment for CRC liver metastasis with single-fraction CIRT appeared to be safe up to 58 Gy (RBE) as long as the central hepatic portal region was avoided., (© 2018 The Authors. Cancer Science published by John Wiley & Sons Australia, Ltd on behalf of Japanese Cancer Association.)

Published

2019

39. Potential lethal damage repair in glioblastoma cells irradiated with ion beams of various types and levels of linear energy transfer.

Author

Chew MT, Nisbet A, Suzuki M, Matsufuji N, Murakami T, Jones B, and Bradley DA

Subjects

Cell Line, Tumor, Cell Survival radiation effects, Glioblastoma pathology, Humans, X-Rays, DNA Damage, DNA Repair, Glioblastoma radiotherapy, Heavy Ions, Linear Energy Transfer

Abstract

Glioblastoma (GBM), a Grade IV brain tumour, is a well-known radioresistant cancer. To investigate one of the causes of radioresistance, we studied the capacity for potential lethal damage repair (PLDR) of three altered strains of GBM: T98G, U87 and LN18, irradiated with various ions and various levels of linear energy transfer (LET). The GBM cells were exposed to 12C and 28Si ion beams with LETs of 55, 100 and 200 keV/μm, and with X-ray beams of 1.7 keV/μm. Mono-energetic 12C ions and 28Si ions were generated by the Heavy Ion Medical Accelerator at the National Institute of Radiological Science, Chiba, Japan. Clonogenic assays were used to determine cell inactivation. The ability of the cells to repair potential lethal damage was demonstrated by allowing one identical set of irradiated cells to repair for 24 h before subplating. The results show there is definite PLDR with X-rays, some evidence of PLDR at 55 keV/μm, and minimal PLDR at 100 keV/μm. There is no observable PLDR at 200 keV/μm. This is the first study, to the authors' knowledge, demonstrating the capability of GBM cells to repair potential lethal damage following charged ion irradiations. It is concluded that a GBM's PLDR is dependent on LET, dose and GBM strain; and the more radioresistant the cell strain, the greater the PLDR.

Published

2019

40. Tumor Control Probability Analysis for Single-Fraction Carbon-Ion Radiation Therapy of Early-Stage Non-small Cell Lung Cancer.

Author

Paz AE, Yamamoto N, Sakama M, Matsufuji N, and Kanai T

Subjects

Humans, Monte Carlo Method, Neoplasm Staging, Probability, Treatment Outcome, Carcinoma, Non-Small-Cell Lung pathology, Carcinoma, Non-Small-Cell Lung radiotherapy, Dose Fractionation, Radiation, Heavy Ion Radiotherapy, Lung Neoplasms pathology, Lung Neoplasms radiotherapy

Abstract

Purpose: To investigate the suitability of the linear-quadratic (LQ) and universal survival curve (USC) models in describing the 3-year tumor control probability data of patients with stage I non-small cell lung cancer treated with carbon-ion radiation therapy. Carbon-ion radiation therapy was given at a total dose of 59.4 to 95.4 Gy (relative biological effectiveness [RBE]) in 18 fractions, at 72 Gy[RBE] in 9 fractions, at 52.8 to 60 Gy[RBE] in 4 fractions, and at 28 to 50 Gy[RBE] in a single fraction., Methods and Materials: A meta-analysis of published clinical data from 394 patients presenting with early-stage non-small cell lung cancer was conducted. Tumor control probability modeling based on the LQ and USC models was performed by simultaneously fitting the clinical data obtained from the different fractionation schedules while considering several spread-out Bragg peak (SOBP) sizes. Radiobiological parameters were derived from the fit. On the basis of the results, a novel SOBP was created for the single-fraction regimen that was optimized with respect to the USC model and aimed at achieving a 95% local control., Results: The USC model gave a better fit to the 3-year local control data than the LQ model did. The fit using various SOBP sizes yielded transition doses between 5.6 and 7.0 Gy. The results also revealed α/β ratios between 7.4 and 9.1 Gy for the LQ model and between 7.4 and 9.4 Gy for the USC model., Conclusions: The USC model provided a better estimate of the local control rate for the single-fraction course. For the schemes with a greater number of fractions, the local control rate estimates from the LQ and USC models were comparable. A USC-based SOBP design was then created for the single-fraction schedule. The updated design resulted in a flatter RBE profile compared with the conventional SOBP design. It also gave a better clinical dose prediction to optimize the tumor control rate., (Copyright © 2018 Gunma University. Published by Elsevier Inc. All rights reserved.)

Published

2018

41. Radiobiological issues in prospective carbon ion therapy trials.

Author

Fossati P, Matsufuji N, Kamada T, and Karger CP

Subjects

Humans, Relative Biological Effectiveness, Clinical Trials as Topic, Heavy Ion Radiotherapy methods, Radiobiology

Abstract

Carbon ion radiotherapy (CIRT) is developing toward a versatile tool in radiotherapy; however, the increased relative biological effectiveness (RBE) of carbon ions in tumors and normal tissues with respect to photon irradiation has to be considered by mathematical models in treatment planning. As a consequence, dose prescription and definition of dose constraints are performed in terms of RBE weighted rather than absorbed dose. The RBE is a complex quantity, which depends on physical variables, such as dose and beam quality as well as on normal tissue- or tumor-specific factors. At present, three RBE models are employed in CIRT: (a) the mixed-beam model, (b) the Microdosimetric Kinetic Model (MKM), and (c) the local effect model. While the LEM is used in Europe, the other two models are employed in Japan, and unfortunately, the concepts of how the nominal RBE-weighted dose is determined and prescribed differ significantly between the European and Japanese centers complicating the comparison, transfer, and reproduction of clinical results. This has severe impact on the way treatments should be prescribed, recorded, and reported. This contribution reviews the concept of the clinical application of the different RBE models and the ongoing clinical CIRT trials in Japan and Europe. Limitations of the RBE models and the resulting radiobiological issues in clinical CIRT trials are discussed in the context of current clinical evidence and future challenges., (© 2017 American Association of Physicists in Medicine.)

Published

2018

42. MICRODOSIMETRIC APPLICATIONS IN PROTON AND HEAVY ION THERAPY USING SILICON MICRODOSIMETERS.

Author

Chartier L, Tran LT, Bolst D, Guatelli S, Pogossov A, Prokopovich DA, Reinhard MI, Perevertaylo V, Anderson S, Beltran C, Matsufuji N, Jackson M, and Rosenfeld AB

Subjects

Computer Simulation, Humans, Radiometry methods, Radiotherapy Dosage, Heavy Ion Radiotherapy methods, Microtechnology instrumentation, Phantoms, Imaging, Proton Therapy methods, Radiometry instrumentation, Radiotherapy Planning, Computer-Assisted methods, Silicon chemistry

Abstract

Using the CMRP 'bridge' μ+ probe, microdosimetric measurements were undertaken out-of-field using a therapeutic scanning proton pencil beam and in-field using a 12C ion therapy field. These measurements were undertaken at Mayo Clinic, Rochester, USA and at HIMAC, Chiba, Japan, respectively. For a typical proton field used in the treatment of deep-seated tumors, we observed dose-equivalent values ranging from 0.62 to 0.99 mSv/Gy at locations downstream of the distal edge. Lateral measurements at depths close to the entrance and along the SOBP plateau were found to reach maximum values of 3.1 mSv/Gy and 5.3 mSv/Gy at 10 mm from the field edge, respectively, and decreased to ~0.04 mSv/Gy 120 mm from the field edge. The ability to measure the dose-equivalent with high spatial resolution is particularly relevant to healthy tissue dose calculations in hadron therapy treatments. We have also shown qualitatively and quantitively the effects critical organ motion would have in treatment using microdosimetric spectra. Large differences in spectra and RBE10 were observed for treatments where miscalculations of 12C ion range would result in critical structures being irradiated, showing the importance of motion management.

Published

2018

43. Monte Carlo study of out-of-field exposure in carbon-ion radiotherapy with a passive beam: Organ doses in prostate cancer treatment.

Author

Yonai S, Matsufuji N, and Akahane K

Subjects

Humans, Male, Phantoms, Imaging, Heavy Ion Radiotherapy methods, Monte Carlo Method, Prostatic Neoplasms radiotherapy

Abstract

Purpose: The aim of this work was to estimate typical dose equivalents to out-of-field organs during carbon-ion radiotherapy (CIRT) with a passive beam for prostate cancer treatment. Additionally, sensitivity analyses of organ doses for various beam parameters and phantom sizes were performed., Methods: Because the CIRT out-of-field dose depends on the beam parameters, the typical values of those parameters were determined from statistical data on the target properties of patients who received CIRT at the Heavy-Ion Medical Accelerator in Chiba (HIMAC). Using these typical beam-parameter values, out-of-field organ dose equivalents during CIRT for typical prostate treatment were estimated by Monte Carlo simulations using the Particle and Heavy-Ion Transport Code System (PHITS) and the ICRP reference phantom., Results: The results showed that the dose decreased with distance from the target, ranging from 116 mSv in the testes to 7 mSv in the brain. The organ dose equivalents per treatment dose were lower than those either in 6-MV intensity-modulated radiotherapy or in brachytherapy with an Ir-192 source for organs within 40 cm of the target. Sensitivity analyses established that the differences from typical values were within ∼30% for all organs, except the sigmoid colon., Conclusions: The typical out-of-field organ dose equivalents during passive-beam CIRT were shown. The low sensitivity of the dose equivalent in organs farther than 20 cm from the target indicated that individual dose assessments required for retrospective epidemiological studies may be limited to organs around the target in cases of passive-beam CIRT for prostate cancer., (Copyright © 2018 Associazione Italiana di Fisica Medica. Published by Elsevier Ltd. All rights reserved.)

Published

2018

44. Correction to: Estimation of linear energy transfer distribution for broad-beam carbon-ion radiotherapy at the National Institute of Radiological Sciences, Japan.

Author

Kanematsu N, Matsufuji N, and Inaniwa T

Abstract

The original version of this article unfortunately contained a mistake. Figure 2 was published with fake signals in panels (a) and (b) which are corrected in this Erratum. The authors are not responsible for this procedural lapse.

Published

2018

45. Estimation of linear energy transfer distribution for broad-beam carbon-ion radiotherapy at the National Institute of Radiological Sciences, Japan.

Author

Kanematsu N, Matsufuji N, and Inaniwa T

Subjects

Humans, Japan, Academies and Institutes, Heavy Ion Radiotherapy, Linear Energy Transfer, Radiobiology

Abstract

A treatment of carbon-ion radiotherapy (CIRT) is generally evaluated using the dose weighted by relative biological effectiveness (RBE) while ignoring the radiation quality varying in the patient. In this study, we have developed a method of estimating linear energy transfer (LET) from the RBE in an archived treatment plan to represent the radiation quality of the treatment. The LET in a beam database was associated with the RBE by two fitting functions per energy, one for the spread-out Bragg peak (SOBP) and the other for shallower depths, to be differentiated by RBE per energy per modulation. The estimated LET was generally consistent with the original calculation within a few keV/μm, except for the overkill region near the distal end of SOBP. The knowledge of experimental radiobiology can thereby be associated with CIRT treatments through LET, which will potentially contribute to deeper understanding of clinical radiobiology and further optimization of CIRT.

Published

2018

46. The relative biological effectiveness for carbon, nitrogen, and oxygen ion beams using passive and scanning techniques evaluated with fully 3D silicon microdosimeters.

Author

Tran LT, Bolst D, Guatelli S, Pogossov A, Petasecca M, Lerch MLF, Chartier L, Prokopovich DA, Reinhard MI, Povoli M, Kok A, Perevertaylo VL, Matsufuji N, Kanai T, Jackson M, and Rosenfeld AB

Subjects

Relative Biological Effectiveness, Carbon therapeutic use, Nitrogen therapeutic use, Oxygen therapeutic use, Radiometry instrumentation, Silicon

Abstract

Background: The aim of this study was to measure the microdosimetric distributions of a carbon pencil beam scanning (PBS) and passive scattering system as well as to evaluate the relative biological effectiveness (RBE) of different ions, namely 12 C, 14 N, and 16 O, using a silicon-on-insulator (SOI) microdosimeter with well-defined 3D-sensitive volumes (SV). Geant4 simulations were performed with the same experimental setup and results were compared to the experimental results for benchmarking., Method: Two different silicon microdosimeters with rectangular parallelepiped and cylindrical shaped SVs, both 10 μm in thickness were used in this study. The microdosimeters were connected to low noise electronics which allowed for the detection of lineal energies as low as 0.15 keV/μm in tissue. The silicon microdosimeters provide extremely high spatial resolution and can be used for in-field and out-of-field measurements in both passive scattering and PBS deliveries. The response of the microdosimeters was studied in 290 MeV/u 12 C, 180 MeV/u 14 N, 400 MeV/u 16 O passive ion beams, and 290 MeV/u 12 C scanning carbon therapy beam at heavy ion medical accelerator in Chiba (HIMAC) and Gunma University Heavy Ion Medical Center (GHMC), Japan, respectively. The microdosimeters were placed at various depths in a water phantom along the central axis of the ion beam, and at the distal part of the Spread Out Bragg Peak (SOBP) in 0.5 mm increments. The RBE values of the pristine Bragg peak (BP) and SOBP were derived using the microdosimetric lineal energy spectra and the modified microdosimetric kinetic model (MKM), using MKM input parameters corresponding to human salivary gland (HSG) tumor cells. Geant4 simulations were performed in order to verify the calculated depth-dose distribution from the treatment planning system (TPS) and to compare the simulated dose-mean lineal energy to the experimental results., Results: For a 180 MeV/u 14 N pristine BP, the dose-mean lineal energy yD¯ obtained with two types of silicon microdosimeters started from approximately 29 keV/μm at the entrance to 92 keV/μm at the BP, with a maximum value in the range of 412 to 438 keV/μm at the distal edge. For 400 MeV/u 16 O ions, the dose-mean lineal energy yD¯ started from about 24 keV/μm at the entrance to 106 keV/μm at the BP, with a maximum value of approximately 381 keV/μm at the distal edge. The maximum derived RBE 10 values for 14 N and 16 O ions were found to be 3.10 ± 0.47 and 2.93 ± 0.45, respectively. Silicon microdosimetry measurements using pencilbeam scanning 12 C ions were also compared to the passive scattering beam., Conclusions: These SOI microdosimeters with well-defined three-dimensional (3D) SVs have applicability in characterizing heavy ion radiation fields and measuring lineal energy deposition with sub-millimeter spatial resolution. It has been shown that the dose-mean lineal energy increased significantly at the distal part of the BP and SOBP due to very high LET particles. Good agreement was observed for the experimental and simulation results obtained with silicon microdosimeters in 14 N and 16 O ion beams, confirming the potential application of SOI microdosimeter with 3D SV for quality assurance in charged particle therapy., (© 2018 American Association of Physicists in Medicine.)

Published

2018

47. Present developments in reaching an international consensus for a model-based approach to particle beam therapy.

Author

Prayongrat A, Umegaki K, van der Schaaf A, Koong AC, Lin SH, Whitaker T, McNutt T, Matsufuji N, Graves E, Mizuta M, Ogawa K, Date H, Moriwaki K, Ito YM, Kobashi K, Dekura Y, Shimizu S, and Shirato H

Subjects

Humans, Neoplasms radiotherapy, Probability, Consensus, Heavy Ion Radiotherapy, Internationality, Models, Theoretical, Proton Therapy

Abstract

Particle beam therapy (PBT), including proton and carbon ion therapy, is an emerging innovative treatment for cancer patients. Due to the high cost of and limited access to treatment, meticulous selection of patients who would benefit most from PBT, when compared with standard X-ray therapy (XRT), is necessary. Due to the cost and labor involved in randomized controlled trials, the model-based approach (MBA) is used as an alternative means of establishing scientific evidence in medicine, and it can be improved continuously. Good databases and reasonable models are crucial for the reliability of this approach. The tumor control probability and normal tissue complication probability models are good illustrations of the advantages of PBT, but pre-existing NTCP models have been derived from historical patient treatments from the XRT era. This highlights the necessity of prospectively analyzing specific treatment-related toxicities in order to develop PBT-compatible models. An international consensus has been reached at the Global Institution for Collaborative Research and Education (GI-CoRE) joint symposium, concluding that a systematically developed model is required for model accuracy and performance. Six important steps that need to be observed in these considerations include patient selection, treatment planning, beam delivery, dose verification, response assessment, and data analysis. Advanced technologies in radiotherapy and computer science can be integrated to improve the efficacy of a treatment. Model validation and appropriately defined thresholds in a cost-effectiveness centered manner, together with quality assurance in the treatment planning, have to be achieved prior to clinical implementation.

Published

2018

48. Selection of carbon beam therapy: biophysical models of carbon beam therapy.

Author

Matsufuji N

Subjects

Carcinoma, Non-Small-Cell Lung radiotherapy, Humans, Lung Neoplasms radiotherapy, Probability, Relative Biological Effectiveness, Biophysical Phenomena, Heavy Ion Radiotherapy

Abstract

Variation in the relative biological effectiveness (RBE) within the irradiation field of a carbon beam makes carbon-ion radiotherapy unique and advantageous in delivering the therapeutic dose to a deep-seated tumor, while sparing surrounding normal tissues. However, it is crucial to consider the RBE, not only in designing the dose distribution during treatment planning, but also in analyzing the clinical response retrospectively. At the National Institute of Radiological Sciences, the RBE model was established based on the response of human salivary gland cells. The response was originally handled with a linear-quadratic model, and later with a microdosimetric kinetic model. Retrospective analysis with a tumor-control probability model of non-small cell cancer treatment revealed a steep dose response in the tumor, and that the RBE of the tumor was adequately estimated using the model. A commonly used normal tissue complication probability model has not yet fully been accountable for the variable RBE of carbon ions; however, analysis of rectum injury after prostate cancer treatment suggested a highly serial-organ structure for the rectum, and a steep dose response similar to that observed for tumors.

Published

2018

49. A silicon strip detector array for energy verification and quality assurance in heavy ion therapy.

Author

Debrot E, Newall M, Guatelli S, Petasecca M, Matsufuji N, and Rosenfeld AB

Subjects

Equipment Design, Monte Carlo Method, Quality Control, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Heavy Ion Radiotherapy, Radiometry instrumentation, Silicon

Abstract

Purpose: The measurement of depth dose profiles for range and energy verification of heavy ion beams is an important aspect of quality assurance procedures for heavy ion therapy facilities. The steep dose gradients in the Bragg peak region of these profiles require the use of detectors with high spatial resolution. The aim of this work is to characterize a one dimensional monolithic silicon detector array called the "serial Dose Magnifying Glass" (sDMG) as an independent ion beam energy and range verification system used for quality assurance conducted for ion beams used in heavy ion therapy., Methods: The sDMG detector consists of two linear arrays of 128 silicon sensitive volumes each with an effective size of 2mm × 50μm × 100μm fabricated on a p-type substrate at a pitch of 200 μm along a single axis of detection. The detector was characterized for beam energy and range verification by measuring the response of the detector when irradiated with a 290 MeV/u 12 C ion broad beam incident along the single axis of the detector embedded in a PMMA phantom. The energy of the 12 C ion beam incident on the detector and the residual energy of an ion beam incident on the phantom was determined from the measured Bragg peak position in the sDMG. Ad hoc Monte Carlo simulations of the experimental setup were also performed to give further insight into the detector response., Results: The relative response profiles along the single axis measured with the sDMG detector were found to have good agreement between experiment and simulation with the position of the Bragg peak determined to fall within 0.2 mm or 1.1% of the range in the detector for the two cases. The energy of the beam incident on the detector was found to vary less than 1% between experiment and simulation. The beam energy incident on the phantom was determined to be (280.9 ± 0.8) MeV/u from the experimental and (280.9 ± 0.2) MeV/u from the simulated profiles. These values coincide with the expected energy of 281 MeV/u., Conclusions: The sDMG detector response was studied experimentally and characterized using a Monte Carlo simulation. The sDMG detector was found to accurately determine the 12 C beam energy and is suited for fast energy and range verification quality assurance. It is proposed that the sDMG is also applicable for verification of treatment planning systems that rely on particle range., (© 2017 American Association of Physicists in Medicine.)

Published

2018

50. Prognostic analysis of radiation pneumonitis: carbon-ion radiotherapy in patients with locally advanced lung cancer.

Author

Hayashi K, Yamamoto N, Karube M, Nakajima M, Matsufuji N, Tsuji H, Ogawa K, and Kamada T

Subjects

Adenocarcinoma pathology, Aged, Aged, 80 and over, Carcinoma, Large Cell pathology, Carcinoma, Non-Small-Cell Lung pathology, Carcinoma, Squamous Cell pathology, Female, Follow-Up Studies, Humans, Lung Neoplasms pathology, Male, Middle Aged, Prognosis, Radiation Pneumonitis diagnosis, Radiotherapy Dosage, Retrospective Studies, Adenocarcinoma radiotherapy, Carcinoma, Large Cell radiotherapy, Carcinoma, Non-Small-Cell Lung radiotherapy, Carcinoma, Squamous Cell radiotherapy, Heavy Ion Radiotherapy adverse effects, Lung Neoplasms radiotherapy, Radiation Pneumonitis etiology

Abstract

Background: Carbon-ion radiotherapy (CIRT) is a promising treatment for locally advanced non-small-cell lung cancer, especially for patients with inoperable lung cancer. Although the incidence of CIRT-induced radiation pneumonitis (RP) ≥ grade 2 ranges from 2.5 to 9.9%, the association between CIRT-induced RP and dosimetric parameters is not clear. Herein, we identified prognostic factors associated with symptomatic RP after CIRT for patients with non-small-cell lung cancer., Methods: Clinical results of 65 patients treated with CIRT between 2000 and 2015 at the National Institute of Radiological Sciences were retrospectively analyzed. Clinical stage II B disease (TNM classification) was the most common stage among the patients (45%). The median radiation dose was 72 Gy (68-76) relative biological effectiveness (RBE) in 16 fractions. In cases involving metastatic lymph nodes, prophylactic irradiation of mediastinal lymph nodes was performed at a median dose of 49.5 Gy (RBE). The median follow-up was 22 months., Results: Grade 2 and grade 3 RP occurred in 6 and 3 patients (9 and 5%), respectively. No patients developed grade 4 or 5 RP. Using univariate analysis, vital capacity as a percentage of predicted (%VC), forced expiratory volume in 1 s (FEV1), mean lung dose (MLD), volume of lung receiving ≥5 Gy (RBE) (V 5 ), V 10 , V 20 and V 30 were determined to be the significant predictive factors for ≥ grade 2 RP. The receiver operating characteristic (ROC) analysis revealed the cutoff values for %VC, FEV1, MLD, V 5 , V 10 , V 20 and V 30 for ≥ grade 2 RP, which were 86.9%, 1.16 L, 12.5 Gy (RBE), 28.8, 29.9, 20.1 and 15.0%, respectively. In addition, the multivariate analysis revealed that %VC <86.9% (odds ratio = 13.7; p = 0.0041) and V 30  ≥ 15% (odds ratio = 6.1; p = 0.0221) were significant risk factors., Conclusions: Our study demonstrated the risk factors for ≥ grade 2 RP after carbon-ion radiotherapy for patients with locally advanced lung cancer.

Published

2017