Your search keyword '"TEPC"' showing total 10 results

1. Microdosimetric Measurements in Gamma and neutron Fields with a Tissue Equivalent Proportional Counter Based on a Gas Electron Multiplier

Author

F. Dal Corso, Matteo Pegoraro, and L. De Nardo

Subjects

Physics::Medical Physics, Proportional counter, Microdosimetry, Electrons, Electron, Radiation Dosage, Particle detector, 030218 nuclear medicine & medical imaging, Nuclear physics, 03 medical and health sciences, Radiation Protection, 0302 clinical medicine, Microdosimetry, TEPC, GEM, Proportional counter, TEPC, Relative biological effectiveness, Humans, Radiology, Nuclear Medicine and imaging, Neutron, Radiometry, Neutrons, Physics, GEM, Radiation, Radiological and Ultrasound Technology, Public Health, Environmental and Occupational Health, Equipment Design, General Medicine, Neutron temperature, Computational physics, 030220 oncology & carcinogenesis, Measuring instrument, Gas electron multiplier, Relative Biological Effectiveness

Abstract

A multi-element tissue-equivalent proportional counter (TEPC), based on a single gas electron multiplier (GEM) foil of standard geometry, has been constructed with 16 cylindrical sensitives volumes. In this article, the design of this novel counter is described and first microdosimetric measurements are presented. To study the response of the GEM-TEPC to both low and high linear energy transfer radiation fields, the microdosimetric spectra due to a 137Cs gamma-ray source and to fast neutrons from 7Li(d,n)8Be reaction have been measured using pure propane gas at low pressure, in order to simulate a tissue site of about 1 µm equivalent size. The comparison with spectra measured with a spherical TEPC and with a mini-TEPC demonstrates promising properties for application of the GEM-TEPC for microdosimetric applications.

Published

2016

2. Monte Carlo simulation of mini TEPC microdosimetric spectra: Influence of low energy electrons

Author

S. Rollet, P. Colautti, Bernd Grosswendt, E. Gargioni, D. Moro, L. DeNardo, and V. Conte

Subjects

Physics, Radiation, Photon, Physics::Medical Physics, Monte Carlo method, TEPC, Tissue equivalent proportional counter, FLUKA, Electron, Particle detector, Computational physics, Ionization, Calibration, Measuring instrument, Statistical physics, Instrumentation

Abstract

In the past few years, miniaturized tissue-equivalent gas detectors (mini TEPCs) have been developed for application of microdosimetry in radiotherapy. These mini-TEPCs are characterised by millimetric dimensions. They are equipped neither with an internal calibration source nor with electric field tubes, which would properly define the sensitive volume hence the simulated site size. In spite of these lacks, mini TEPCs working in gas flow conditions have proven to be precise and reliable detectors. However, for future therapeutic plans including microdosimetric data, consistency between experimental and calculated data is important. Existing general-purpose Monte Carlo codes have proven to be very useful to calculate the energy deposition due to ionization in macroscopic targets, even in various complex radiation fields. However, theoretical models implemented in these codes for simulating electron transport and straggling are valid only for energies above a few keV. This restricts their applicability for simulating radiation transport at a micrometric level, where low-energy electrons play a dominant role. In this work, we calculate frequency distributions of deposited energy in a mini TEPC (with sizes equivalent to 1 and 2 μm) due to photons using the Monte Carlo code FLUKA. Comparisons between simulated and experimental data show a rather good agreement. Differences due to different FLUKA settings are discussed.

Published

2010

3. BNCT dosimetry performed with a mini twin tissue-equivalent proportional counters (TEPC)

Author

V. Conte, P. Colautti, Juan Esposito, M. Lollo, L. De Nardo, D. Moro, A. Ferretti, and C. Ceballos

Subjects

Nuclear engineering, Physics::Medical Physics, Monte Carlo method, Microdosimetry, Boron Neutron Capture Therapy, TAPIRO, Radiation, TEPC, Nuclear Reactors, BNCT, HYTHOR, Relative biological effectiveness, Humans, Dosimetry, Linear Energy Transfer, Irradiation, Physics, Dosimeter, Radiotherapy Planning, Computer-Assisted, Radiochemistry, Detector, Equipment Design, Italy, Absorbed dose, Monte Carlo Method, Relative Biological Effectiveness

Abstract

The BNCT radiation field is complex because different beam components are mixed, each one having different relative biological effectiveness (RBE). Microdosimetry with tissue-equivalent proportional counters (TEPC) has proven to be an ideal dosimetric technique for mixed radiation fields, because it is able both to measure the absorbed dose and to assess the radiation field relative biological effectiveness with good accuracy. An ideal detector for BNCT should contain two TEPCs, one detector loaded with, while the other one without (10)B in order to record all beam components with a unique measurement. Moreover, such a detector should be of tiny size in order to be able to measure in the intense BNCT radiation fields without significant pile-up effects. TEPCs have been shown to be pretty good dosimeters for mixed radiation fields. In this paper the first mini twin TEPC counter for BNCT is presented, as well as first measurement at the new HYTHOR thermal irradiation facility at TAPIRO nuclear reactor and comparison with related Monte Carlo calculations.

Published

2009

4. Equivalence of pure propane and propane TE gases for microdosimetric measurements

Author

D. Moro, V. Conte, Bernd Grosswendt, S. Chiriotti, P. Colautti, Belgian Nuclear Research Centre, SCK-CEN, Mol, Belgium - Radiation Protection Dosimetry and Calibration Expert Group, and UCL - SSS/IREC/MIRO - Pôle d'imagerie moléculaire, radiothérapie et oncologie

Subjects

Materials science, Physics::Medical Physics, propane-TE, Proportional counter, Microdosimetry, pure propane, Radiation Dosage, Ion, chemistry.chemical_compound, Propane, TEPC, Radiology, Nuclear Medicine and imaging, Neutron, Computer Simulation, Radiometry, Equivalence (measure theory), Neutrons, Radiation, Radiological and Ultrasound Technology, Detector, Public Health, Environmental and Occupational Health, General Medicine, Gas gain, chemistry, Calibration, Microtechnology, Atomic physics, Protons, Tissue volume

Abstract

A tissue-equivalent proportional counter (TEPC) simulates micrometric volumes of tissue if the energy deposited in the counter cavity is the same as that in the tissue volume. Nevertheless, a TEPC measures only the ionisations created in the gas, which are later converted into imparted energy. Therefore, the equivalence of the simulated diameter (Dρ) in two gases should be based on the equality of the mean number of ions pairs in the gas rather than on the imparted energy. Propane-based tissue-equivalent gas is the most commonly used gas mixture at present, but it has the drawback that its composition may change with time. From this point of view, the use of pure propane offers practical advantages: higher gas gain and longer stability. In this work, microdosimetric measurements performed with pure propane, at site sizes 0.05 mg cm(-2) ≤ Dρ ≤ 0.3 mg cm(-2), demonstrate that the response of a propane-filled detector in gamma and in neutron fields is almost the same if an appropriate gas density is used.

Published

2015

5. Microdosimetric investigation at the therapeutic proton beam facility of CATANA

Author

L. De Nardo, Giacomo Cuttone, P. Colautti, G. Tornielli, V. Conte, and D. Moro

Subjects

Proton, Microdosimetry, Proton therapy, TEPC, Radiation quality, Sobp, Proportional counter, Risk Assessment, Sensitivity and Specificity, Nuclear physics, Radiation Protection, Proton Therapy, Humans, Linear Energy Transfer, Radiology, Nuclear Medicine and imaging, Radiometry, Physics, Radiation, Radiological and Ultrasound Technology, Radiotherapy Planning, Computer-Assisted, Public Health, Environmental and Occupational Health, Reproducibility of Results, Radiotherapy Dosage, Equipment Design, General Medicine, Equipment Failure Analysis, Italy, Body Burden, Radiotherapy, Conformal, Algorithms, Relative Biological Effectiveness, Beam (structure)

Abstract

Proton beams (62 Mev) are used by the Laboratori Nazionali del Sud of the Italian Institute of Nuclear Physics to treat eye melanoma tumours at the therapeutic facility called CATANA. A cylindrical slim tissue-equivalent proportional counter (TEPC) of 2.7 mm external diameter has been used to compare the radiation quality of two spread-out Bragg peaks (SOBP) at the CATANA proton beam.

Published

2004

6. Response calculations for silicon-based direct-reading dosimeters for use at the international space station (ISS)

Author

S. Rollet, M. Luszik-Bhadra, Aleksandar B. Jakšić, M. Latocha, A. Zechner, M. Vuotila, Günther Reitz, Peter Beck, and Thomas Berger

Subjects

Physics, Radiation, Dosimeter, business.industry, Equivalent dose, ISS, Direct reading, Detector, Proportional counter, Silicon based, FLUKA, PHITS, Optics, TEPC, Absorbed dose, International Space Station, Silicon detectors, business, Nuclear medicine, Instrumentation, GEANT4

Abstract

In 2007, the European Space Agency (ESA) initiated the development of European Crew Personal Active Dosimeters. The hardware development objective is to produce an active personal dosimeter which shows absorbed dose and dose equivalent spectra similar to a Tissue Equivalent Proportional Counter (TEPC), but which is based on more robust silicon detector devices. Several detector/dosimeter components have been investigated – by computer simulations – for their performance in the radiation field at the ISS position.

Published

2010

7. First microdosimetric measurements with a TEPC based on a GEM

Author

Adrie J. J. Bos, L. De Nardo, C.W.E. van Eijk, and M. Farahmand

Subjects

Quality Control, Physics::Medical Physics, chemistry.chemical_element, Proportional counter, Microdosimetry, Risk Assessment, Sensitivity and Specificity, Linear particle accelerator, Nuclear physics, Radiation Protection, TEPC, Risk Factors, Relative biological effectiveness, Scattering, Radiation, Radiology, Nuclear Medicine and imaging, Neutron, Computer Simulation, Linear Energy Transfer, Radiometry, Physics, Neutrons, GEM, Radiation, Radiological and Ultrasound Technology, business.industry, Public Health, Environmental and Occupational Health, Reproducibility of Results, Californium, General Medicine, Equipment Design, Neutron radiation, Equipment Failure Analysis, chemistry, Scintillation counter, Gas electron multiplier, Body Burden, Computer-Aided Design, Scintillation Counting, Nuclear medicine, business, Algorithms, Relative Biological Effectiveness

Abstract

A new type of mini multi-element tissue-equivalent proportional counter (TEPC) based on a gas electron multiplier (GEM) has been designed and constructed. This counter is in particular suitable to be constructed with a small sensitive volume so that it can be used for microdosimetry in intense pulsed radiation fields to measure the microdosimetric spectrum in the beam of, for instance, a clinical linear accelerator. The concept lends itself also for a mini multi-element version of the counter to be used for applications in which a high sensitivity is required. In this paper, we present the first microdosimetric measurements of this novel counter exposed to a 14 MeV monoenergetic neutron beam and a californium (252Cf) source for a counter cavity diameter of 1.8 mm simulating 1.0 microm tissue site size. The measured spectra showed an excellent agreement with spectra from the literature. The specific advantages of the TEPC-GEM are discussed.

Published

2004

8. Mini-TEPCs for radiation therapy

Author

L. De Nardo, G. Magrin, P. Colautti, G. Donà, V. Cesari, V. Conte, and G. Tornielli

Subjects

Therapeutic proton beam, Proton, medicine.medical_treatment, Sensitivity and Specificity, Optics, Radiation Protection, TEPC, medicine, Calibration, Radiology, Nuclear Medicine and imaging, Radiometry, Physics, Radiation, Radiological and Ultrasound Technology, Radiotherapy, business.industry, Radiotherapy Planning, Computer-Assisted, Public Health, Environmental and Occupational Health, Gamma ray, Reproducibility of Results, Radiotherapy Dosage, General Medicine, Equipment Design, Radiation therapy, Equipment Failure Analysis, Gamma Rays, Feasibility Studies, Protons, Nuclear medicine, business

Abstract

A mini-tissue-equivalent proportional-counter (TEPC) has been constructed to study the possibility to manufacture mini-counters without field-shaping tubes for radiation therapy. The mini-TEPC can be assembled with and without field-shaping tubes. It can be equipped with a mini-alpha source for a precise lineal energy calibration. After the positive conclusions of this study, a slim TEPC has been designed and constructed. The slim TEPC has an external diameter of only 2.7 mm. It has been tested with therapeutic proton beams and gamma ray sources.

Published

2004

9. Nanodosimetric measurements with an avalanche confinement TEPC

Author

Bernd Grosswendt, V. Cesari, A. Alkaa, L. De Nardo, P. Colautti, G. Magrin, G. Tornielli, P. Ségur, W. Y. Baek, and C. Khamphan

Subjects

Materials science, Physics::Medical Physics, Monte Carlo method, Proportional counter, Microdosimetry, Sensitivity and Specificity, Spectral line, chemistry.chemical_compound, Optics, Propane, TEPC, Radiology, Nuclear Medicine and imaging, Neutron, Dimethyl ether, Radiometry, Monte Carlo simulation, Radiation, Radiological and Ultrasound Technology, business.industry, Resolution (electron density), Public Health, Environmental and Occupational Health, Dose-Response Relationship, Radiation, General Medicine, Equipment Design, chemistry, Gas gain, Scintillation Counting, Atomic physics, business

Abstract

This paper illustrates a tissue-equivalent proportional counter designed to have high gas gain and good energy resolution at nanometric simulated site sizes. Microdosimetric neutron and gamma spectra were measured in dimethyl ether and in propane-based tissue-equivalent gas mixture down to 35 nm. The comparison of experimental data with the results of Monte Carlo calculations shows a satisfactory agreement.

Published

2002

10. Microdosimetric assessment of nice therapeutic proton beam biological quality

Author

Nardo, L., Cesari, V., Iborra, N., Valeria Conte, Colautti, P., Héraul, J., Tornielli, G., and Chauvel, P.

Subjects

TEPC, Microdosimetry, Proton therapy