Your search keyword '"Petasecca, Marco"' showing total 27 results

1. Dosimetry of microbeam radiotherapy by flexible hydrogenated amorphous silicon detectors.

Author

Large MJ, Kanxheri K, Posar J, Aziz S, Bashiri A, Calcagnile L, Calvo D, Caputo D, Caricato AP, Catalano R, Cirio R, Cirrone GAP, Croci T, Cuttone G, De Cesare G, De Remigis P, Dunand S, Fabi M, Frontini L, Grimani C, Guarrera M, Ionica M, Lenta F, Liberali V, Lovecchio N, Martino M, Maruccio G, Mazza G, Menichelli M, Monteduro AG, Morozzi A, Moscatelli F, Nascetti A, Pallotta S, Passeri D, Pedio M, Petringa G, Peverini F, Placidi P, Quarta G, Rizzato S, Sabbatini F, Servoli L, Stabile A, Thomet JE, Tosti L, Villani M, Wheadon RJ, Wyrsch N, Zema N, Petasecca M, and Talamonti C

Subjects

Hydrogen, Radiotherapy instrumentation, Silicon chemistry, Radiometry instrumentation

Abstract

Objective. Detectors that can provide accurate dosimetry for microbeam radiation therapy (MRT) must possess intrinsic radiation hardness, a high dynamic range, and a micron-scale spatial resolution. In this work we characterize hydrogenated amorphous silicon detectors for MRT dosimetry, presenting a novel combination of flexible, ultra-thin and radiation-hard features. Approach. Two detectors are explored: an n-type/intrinsic/p-type planar diode (NIP) and an NIP with an additional charge selective layer (NIP + CSC). Results. The sensitivity of the NIP + CSC detector was greater than the NIP detector for all measurement conditions. At 1 V and 0 kGy under the 3T Cu-Cu synchrotron broadbeam, the NIP + CSC detector sensitivity of (7.76 ± 0.01) pC cGy -1 outperformed the NIP detector sensitivity of (3.55 ± 0.23) pC cGy -1 by 219%. The energy dependence of both detectors matches closely to the attenuation coefficient ratio of silicon against water. Radiation damage measurements of both detectors out to 40 kGy revealed a higher radiation tolerance in the NIP detector compared to the NIP + CSC (17.2% and 33.5% degradations, respectively). Percentage depth dose profiles matched the PTW microDiamond detector's performance to within ±6% for all beam filtrations except in 3T Al-Al due to energy dependence. The 3T Cu-Cu microbeam field profile was reconstructed and returned microbeam width and peak-to-peak values of (51 ± 1) μ m and (405 ± 5) μ m, respectively. The peak-to-valley dose ratio was measured as a function of depth and agrees within error to the values obtained with the PTW microDiamond. X-ray beam induced charge mapping of the detector revealed minimal dose perturbations from extra-cameral materials. Significance. The detectors are comparable to commercially available dosimeters for quality assurance in MRT. With added benefits of being micron-sized and possessing a flexible water-equivalent substrate, these detectors are attractive candidates for quality assurance, in-vivo dosimetry and in-line beam monitoring for MRT and FLASH therapy., (Creative Commons Attribution license.)

Published

2024

2. HDR brachytherapy afterloader quality assurance optimization using monolithic silicon strip detectors.

Author

Hunt B, Cutajar D, Petasecca M, Rosenfeld A, Howie A, Bucci J, and Poder J

Subjects

Quality Assurance, Health Care, Radiometry instrumentation, Radiotherapy Dosage, Quality Control, Brachytherapy instrumentation, Silicon

Abstract

Background: There currently exists no widespread high dose-rate (HDR) brachytherapy afterloader quality assurance (QA) tool for simultaneously assessing the afterloader's positional, temporal, transit velocity and air kerma strength accuracy., Purpose: The purpose of this study was to develop a precise and rigorous technique for performing daily QA of HDR brachytherapy afterloaders, incorporating QA of: dwell position accuracy, dwell time accuracy, transit velocity consistency and relative air kerma strength (AKS) of an Ir-192 source., Method: A Sharp ProGuide 240 mm catheter (Elekta Brachytherapy, Veenendaal, The Netherlands) was fixed 5 mm above a 256 channel epitaxial diode array 'dose magnifying glass' (DMG256) (Centre for Medical and Radiation Physics, University of Wollongong). Three dwell positions, each of 5.0 s dwell times, were spaced 13.0 mm apart along the array with the Flexitron HDR afterloader (Elekta Brachytherapy, Veenendaal, The Netherlands). The DMG256 was connected to a data acquisition system (DAQ) and a computer via USB2.0 link for live readout and post-processing. The outputted data files were analyzed using a Python script to provide positional and temporal localization of the Ir-192 source by tracking the centroid of the detected response. Measurements were repeated on a weekly basis, for a period of 5 weeks to determine the consistency of the measured parameters over an extended period., Results: Using the DMG256 for relative AKS measurements resulted in measured values within 0.6%-3.0% of the expected activity over a 7-week period. The sub-millisecond temporal accuracy of the device allowed for measurements of the transit velocity with an average of (10.88 ± 1.01) cm/s for 13 mm steps. The dwell position localization for 1, 2, 3, 5, and 10 mm steps had an accuracy between 0.1 and 0.3 mm (3σ), with a fixed temporal accuracy of 10 ms., Conclusion: The DMG256 silicon strip detector allows for clinics to perform rigorous daily QA of HDR afterloader dwell position and dwell time accuracy with greater precision than the current standard methodology using closed circuit television and a stopwatch. Additionally, DMG256 unlocks the ability to perform measurements of transit velocity/time and relative AKS, which are not possible using current standard techniques., (© 2024 The Author(s). Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published

2024

3. Characterization of a flexible a-Si:H detector for in vivo dosimetry in therapeutic x-ray beams.

Author

Large MJ, Bashiri A, Dookie Y, McNamara J, Antognini L, Aziz S, Calcagnile L, Caricato AP, Catalano R, Chila D, Cirrone GAP, Croci T, Cuttone G, Dunand S, Fabi M, Frontini L, Grimani C, Ionica M, Kanxheri K, Liberali V, Maurizio M, Maruccio G, Mazza G, Menichelli M, Monteduro AG, Morozzi A, Moscatelli F, Pallotta S, Passeri D, Pedio M, Petringa G, Peverini F, Piccolo L, Placidi P, Quarta G, Rizzato S, Sabbatini F, Servoli L, Stabile A, Talamonti C, Thomet JE, Tosti L, Villani M, Wheadon RJ, Wyrsch N, Zema N, and Petasecca M

Subjects

Hydrogen, In Vivo Dosimetry, X-Ray Therapy instrumentation, Humans, Silicon, Radiometry instrumentation

Abstract

Background: The increasing use of complex and high dose-rate treatments in radiation therapy necessitates advanced detectors to provide accurate dosimetry. Rather than relying on pre-treatment quality assurance (QA) measurements alone, many countries are now mandating the use of in vivo dosimetry, whereby a dosimeter is placed on the surface of the patient during treatment. Ideally, in vivo detectors should be flexible to conform to a patient's irregular surfaces., Purpose: This study aims to characterize a novel hydrogenated amorphous silicon (a-Si:H) radiation detector for the dosimetry of therapeutic x-ray beams. The detectors are flexible as they are fabricated directly on a flexible polyimide (Kapton) substrate., Methods: The potential of this technology for application as a real-time flexible detector is investigated through a combined dosimetric and flexibility study. Measurements of fundamental dosimetric quantities were obtained including output factor (OF), dose rate dependence (DPP), energy dependence, percentage depth dose (PDD), and angular dependence. The response of the a-Si:H detectors investigated in this study are benchmarked directly against commercially available ionization chambers and solid-state diodes currently employed for QA practices., Results: The a-Si:H detectors exhibit remarkable dose linearities in the direct detection of kV and MV therapeutic x-rays, with calibrated sensitivities ranging from (0.580 ± 0.002) pC/cGy to (19.36 ± 0.10) pC/cGy as a function of detector thickness, area, and applied bias. Regarding dosimetry, the a-Si:H detectors accurately obtained OF measurements that parallel commercially available detector solutions. The PDD response closely matched the expected profile as predicted via Geant4 simulations, a PTW Farmer ionization chamber and a PTW ROOS chamber. The most significant variation in the PDD performance was 5.67%, observed at a depth of 3 mm for detectors operated unbiased. With an external bias, the discrepancy in PDD response from reference data was confined to ± 2.92% for all depths (surface to 250 mm) in water-equivalent plastic. Very little angular dependence is displayed between irradiations at angles of 0° and 180°, with the most significant variation being a 7.71% decrease in collected charge at a 110° relative angle of incidence. Energy dependence and dose per pulse dependence are also reported, with results in agreement with the literature. Most notably, the flexibility of a-Si:H detectors was quantified for sample bending up to a radius of curvature of 7.98 mm, where the recorded photosensitivity degraded by (-4.9 ± 0.6)% of the initial device response when flat. It is essential to mention that this small bending radius is unlikely during in vivo patient dosimetry. In a more realistic scenario, with a bending radius of 15-20 mm, the variation in detector response remained within ± 4%. After substantial bending, the detector's photosensitivity when returned to a flat condition was (99.1 ± 0.5)% of the original response., Conclusions: This work successfully characterizes a flexible detector based on thin-film a-Si:H deposited on a Kapton substrate for applications in therapeutic x-ray dosimetry. The detectors exhibit dosimetric performances that parallel commercially available dosimeters, while also demonstrating excellent flexibility results., (© 2024 The Authors. Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published

2024

4. Hydrogenated amorphous silicon high flux x-ray detectors for synchrotron microbeam radiation therapy.

Author

Large MJ, Bizzarri M, Calcagnile L, Caprai M, Caricato AP, Catalano R, Cirrone GAP, Croci T, Cuttone G, Dunand S, Fabi M, Frontini L, Gianfelici B, Grimani C, Ionica M, Kanxheri K, Lerch MLF, Liberali V, Martino M, Maruccio G, Mazza G, Menichelli M, Monteduro AG, Moscatelli F, Morozzi A, Pallotta S, Papi A, Passeri D, Pedio M, Petringa G, Peverini F, Piccolo L, Placidi P, Quarta G, Rizzato S, Rossi A, Rossi G, de Rover V, Sabbatini F, Servoli L, Stabile A, Talamonti C, Tosti L, Villani M, Wheadon RJ, Wyrsch N, Zema N, and Petasecca M

Subjects

X-Rays, Australia, Radiometry methods, Synchrotrons, Silicon

Abstract

Objective . Microbeam radiation therapy (MRT) is an alternative emerging radiotherapy treatment modality which has demonstrated effective radioresistant tumour control while sparing surrounding healthy tissue in preclinical trials. This apparent selectivity is achieved through MRT combining ultra-high dose rates with micron-scale spatial fractionation of the delivered x-ray treatment field. Quality assurance dosimetry for MRT must therefore overcome a significant challenge, as detectors require both a high dynamic range and a high spatial resolution to perform accurately. Approach . In this work, a series of radiation hard a-Si:H diodes, with different thicknesses and carrier selective contact configurations, have been characterised for x-ray dosimetry and real-time beam monitoring applications in extremely high flux beamlines utilised for MRT at the Australian Synchrotron. Results . These devices displayed superior radiation hardness under constant high dose-rate irradiations on the order of 6000 Gy s -1 , with a variation in response of 10% over a delivered dose range of approximately 600 kGy. Dose linearity of each detector to x-rays with a peak energy of 117 keV is reported, with sensitivities ranging from (2.74 ± 0.02) nC/Gy to (4.96 ± 0.02) nC/Gy. For detectors with 0.8 μ m thick active a-Si:H layer, their operation in an edge-on orientation allows for the reconstruction of micron-size beam profiles (microbeams). The microbeams, with a nominal full-width-half-max of 50 μ m and a peak-to-peak separation of 400 μ m, were reconstructed with extreme accuracy. The full-width-half-max was observed as 55 ± 1 μ m. Evaluation of the peak-to-valley dose ratio and dose-rate dependence of the devices, as well as an x-ray induced charge (XBIC) map of a single pixel is also reported. Significance . These devices based on novel a-Si:H technology possess a unique combination of accurate dosimetric performance and radiation resistance, making them an ideal candidate for x-ray dosimetry in high dose-rate environments such as FLASH and MRT., (Creative Commons Attribution license.)

Published

2023

5. Evaluation of silicon strip detectors in transmission mode for online beam monitoring in microbeam radiation therapy at the Australian Synchrotron.

Author

Davis J, Dipuglia A, Cameron M, Paino J, Cullen A, Guatelli S, Petasecca M, Rosenfeld A, and Lerch M

Subjects

Animals, Australia, Humans, Monte Carlo Method, Radiotherapy Dosage, Silicon, Synchrotrons

Abstract

Successful transition of synchrotron-based microbeam radiation therapy (MRT) from pre-clinical animal studies to human trials is dependent upon ensuring that there are sufficient and adequate measures in place for quality assurance purposes. Transmission detectors provide researchers and clinicians with a real-time quality assurance and beam-monitoring instrument to ensure safe and accurate dose delivery. In this work, the effect of transmission detectors of different thicknesses (10 and 375 µm) upon the photon energy spectra and dose deposition of spatially fractionated synchrotron radiation is quantified experimentally and by means of a dedicated Geant4 simulation study. The simulation and experimental results confirm that the presence of the 375 µm thick transmission detector results in an approximately 1-6% decrease in broad-beam and microbeam peak dose. The capability to account for the reduction in dose and change to the peak-to-valley dose ratio justifies the use of transmission detectors as thick as 375 µm in MRT provided that treatment planning systems are able to account for their presence. The simulation and experimental results confirm that the presence of the 10 µm thick transmission detector shows a negligible impact (<0.5%) on the photon energy spectra, dose delivery and microbeam structure for both broad-beam and microbeam cases. Whilst the use of 375 µm thick detectors would certainly be appropriate, based upon the idea of best practice the authors recommend that 10 µm thick transmission detectors of this sort be utilized as a real-time quality assurance and beam-monitoring tool during MRT., (open access.)

Published

2022

6. High resolution silicon array detector implementation in an inline MRI-linac.

Author

Alnaghy SJ, Causer T, Roberts N, Oborn B, Jelen U, Dong B, Gargett M, Begg J, Liney G, Petasecca M, Rosenfeld AB, Holloway L, and Metcalfe P

Subjects

Magnetic Resonance Imaging instrumentation, Particle Accelerators, Silicon

Abstract

Purpose: Dynamic dosimaging is a concept whereby a detector in motion is tracked with magnetic resonance imaging (MRI) to validate the amount and position of dose in a radiation therapy treatment on an MRI-linac. This work takes steps toward the realization of dynamic dosimaging with the novel high resolution silicon array detector: MagicPlate-512 (M512). The performance of the M512 was assessed in a 1.0 T inline MRI-linac, without simultaneous imaging and then during an imaging sequence, both during dosimetry. MR images were acquired to determine the effect of the detector and its components on image quality., Methods: Beam profiles were measured using the M512 on the Australian MRI-Linac and a comparison made with Gafchromic EBT3 film to investigate any intrinsic magnetic field effects in the silicon. The M512 has 512 sensitive volumes, each 0.5 × 0.5 × 0.037 mm 3 in dimension, organized in a two-dimensional array. Small field sizes up to 4.2 × 3.8 cm 2 were investigated in both solid water and then solid lung phantoms. Beam profiles taken at 1.0 T were compared to 0 T conditions, and also to profiles taken during a gradient echo (GRE) imaging sequence. Differences in 80%-20% penumbral width and full width at half maximum (FWHM) were investigated. Localizer MR images were acquired of the detector adjacent to a water phantom., Results: Good agreement was observed between the M512 and film, with average differences in penumbral width and FWHM of <1 mm in the absence of the imaging sequence. Concurrent imaging widened the penumbra by up to 1.2 mm due to RF noise affecting the detector; film profiles were unchanged. Magnetic resonance images were affected by noise, in particular, due to the large amount of aluminum present, as well as from the USB cable, which acted as an antenna. Unfortunately, due to these issues, suitable dynamic dose imaging was not achieved with the current M512/phantom configuration and the MRI-linac. However, progress was made toward achieving this goal for future work., Conclusions: The M512 silicon array detector successfully measured high-resolution beam profiles in agreement with Gafchromic film to within an average of <1 mm on the first MRI-linac in Australia. More effective noise reduction will be required for the achievement of dynamic dosimaging in the future., (© 2020 American Association of Physicists in Medicine.)

Published

2020

7. First application of a high-resolution silicon detector for proton beam Bragg peak detection in a 0.95 T magnetic field.

Author

Causer TJ, Schellhammer SM, Gantz S, Lühr A, Hoffmann AL, Metcalfe PE, Rosenfeld AB, Guatelli S, Petasecca M, and Oborn BM

Subjects

Signal-To-Noise Ratio, Magnetic Fields, Proton Therapy instrumentation, Radiometry instrumentation, Silicon

Abstract

Purpose: To report on experimental results of a high spatial resolution silicon-based detector exposed to therapeutic quality proton beams in a 0.95 T transverse magnetic field. These experimental results are important for the development of accurate and novel dosimetry methods in future potential real-time MRI-guided proton therapy systems., Methods: A permanent magnet device was utilized to generate a 0.95 T magnetic field over a 4 × 20 × 15 cm 3 volume. Within this volume, a high-resolution silicon diode array detector was positioned inside a PMMA phantom of 4 × 15 × 12 cm 3 . This detector contains two orthogonal strips containing 505 sensitive volumes spaced at 0.2 mm apart. Proton beams collimated to a circle of 10 mm diameter with nominal energies of 90 MeV, 110 MeV, and 125 MeV were incident on the detector from an edge-on orientation. This allows for a measurement of the Bragg peak at 0.2 mm spatial resolution in both the depth and lateral profile directions. The impact of the magnetic field on the proton beams, that is, a small deflection was also investigated. A Geant4 Monte Carlo simulation was performed of the experimental setup to aid in interpretation of the results., Results: The nominal Bragg peak for each proton energy was successfully observed with a 0.2 mm spatial resolution in the 0.95 T transverse magnetic field in both a depth and lateral profiles. The proton beam deflection (at 0.95 T) was a consistent 2 ±0.5 mm at the center of the magnetic volume for each beam energy. However, a pristine Bragg peak was not observed for each energy. This was caused by the detector packaging having small air gaps between layers of the phantom material surrounding the diode array. These air gaps act to degrade the shape of the Bragg peak, and further to this, the nonwater equivalent silicon chip acts to separate the Bragg peak into multiple peaks depending on the proton path taken. Overall, a promising performance of the silicon detector array was observed, however, with a qualitative assessment rather than a robust quantitative dosimetric evaluation at this stage of development., Conclusions: For the first time, a high-resolution silicon-based radiation detector has been used to measure proton beam Bragg peak deflections in a phantom due to a strong magnetic field. Future efforts are required to optimize the detector packaging to strengthen the robustness of the dosimetric quantities obtained from the detector. Such high-resolution silicon diode arrays may be useful in future efforts in MRI-guided proton therapy research., (© 2019 American Association of Physicists in Medicine.)

Published

2020

8. A feasibility study for high-resolution silicon array detector performance in the magnetic field of a permanent magnet system.

Author

Alnaghy SJ, Causer T, Gargett M, Roberts N, Petasecca M, Oborn BM, Rosenfeld AB, Holloway L, and Metcalfe P

Subjects

Calibration, Feasibility Studies, Particle Accelerators, Quality Control, Magnetic Fields, Radiometry instrumentation, Silicon

Abstract

Purpose: Magnetic field effects on dose distribution and detector functionality must be well understood. The detector utilized to investigate these magnetic field effects was the DUO silicon array detector; the performance of this high spatial resolution detector was assessed under these conditions. The results were compared to Gafchromic EBT3 film to highlight any intrinsic magnetic field effects in the silicon. The results were also compared to previously published MagicPlate-512 (M512) data. The DUO has an improved spatial resolution (200 µm) over the M512 (2 mm)., Methods: A permanent magnet named Magnetic Apparatus for RaDiation Oncology Studies (MARDOS) paired with a standard linear accelerator (linac) enables either transverse (1.2 T) or inline (0.95 T) orientations of the magnetic field with respect to the radiation beam. A 6 MV Varian 2100C Linac provided the radiation component for the measurements. The DUO detector has 505 sensitive volumes (each volume measuring 800 × 40 × 100 µm 3 ) organized in two orthogonal, linear arrays. The DUO was embedded in a solid water phantom in the first set-up and then a solid lung phantom in the second set-up and placed between the magnet cones. Beam profiles were compared under the magnetic field conditions and 0 T. Small field sizes from 0.8 × 0.8 cm 2 up to 2.3 × 2.3 cm 2 were investigated. The size of the air gap above the sensitive volumes of the DUO was investigated in the transverse orientation to assess the anticipated magnetic field effects. Full width at half maximum (FWHM), 80-20% penumbral widths and maximum dose differences between detectors and between the presence/absence of a magnetic field were investigated. Symmetry was also assessed for investigation of profile skewness under the transverse field., Results: The penumbral widths measured by the DUO detector demonstrated good agreement with film and the M512 to within an average of 0.5 mm (within uncertainty: ±1 mm). The static inline magnetic field had minimal effect on the profiles in solid water. As expected, the lower density of solid lung meant that this material was more susceptible to demonstrating magnetic field effects in the dose deposited. The greatest penumbral narrowing due to the inline field (0.7 mm) occurred in lung. Central axis dose increase was greatest in lung (maximum: 9%). The transverse field widened penumbra, most notably in the solid lung phantom, by a maximum of 2.3 mm. The largest asymmetry due to the transverse field (4.6%) was also in solid lung. When the air gap above the DUO was filled with bolus, the dose maximum measured by the DUO was within 1.4% of film., Conclusions: The DUO detector has been shown to be successful in accurately describing the dose changes for small field sizes to within a 200-µm resolution in an environment resembling that of an MRI-linac. The DUO measurements were in agreement with both film and the M512 measurements, and therefore the DUO was found to be an appropriate alternative to the M512, with improvement in terms of its higher spatial resolution. MARDOS provided a suitable environment for these preliminary tests before progressing to the MRI-linac., (© 2019 American Association of Physicists in Medicine.)

Published

2019

9. "Characterization of ELEKTA SRS cone collimator using high spatial resolution monolithic silicon detector array".

Author

Shukaili KA, Corde S, Petasecca M, Pereveratylo V, Lerch M, Jackson M, and Rosenfeld A

Subjects

Radiometry, Radiosurgery, Silicon

Abstract

Purpose: To investigate the accuracy of the dosimetry of radiation fields produced by small ELEKTA cone collimators used for stereotactic radiosurgery treatments (SRS) using commercially available detectors EBT3 Gafchromic TM film, IBA Stereotactic diode (SFD), and the recently developed detector DUO, which is a monolithic silicon orthogonal linear diode array detector., Methods: These three detectors were used for the measurement of beam profiles, output factors, and percentage depth dose for SRS cone collimators with cone sizes ranging from 5 to 50 mm diameter. The measurements were performed at 10 cm depth and 90 cm SSD., Results: The SRS cone beam profiles measured with DUO, EBT3 film, and IBA SFD agreed well, results being in agreement within ±0.5 mm in the FWHM, and ±0.7 mm in the penumbra region. The output factor measured by DUO with 0.5 mm air gap above agrees within ±1% with EBT3. The OF measured by IBA SFD (corrected for the over-response) agreed with both EBT3 and DUO within ±2%. All three detectors agree within ±2% for PDD measurements for all SRS cones., Conclusions: The characteristics of the ELEKTA SRS cone collimator have been evaluated by using a monolithic silicon high spatial resolution detector DUO, EBT3, and IBA SFD diode. The DUO detector is suitable for fast real-time quality assurance dosimetry in small radiation fields typical for SRS/SRT. This has been demonstrated by its good agreement of measured doses with EBT 3 films., (© 2018 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, Inc. on behalf of American Association of Physicists in Medicine.)

Published

2018

10. 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

11. 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

12. Impact of a monolithic silicon detector operating in transmission mode on clinical photon beams.

Author

Utitsarn K, Alrowaili ZA, Stansook N, Petasecca M, Carolan M, Perevertaylo VL, Lerch M, and Rosenfeld A

Subjects

Humans, Phantoms, Imaging, Radiosurgery, Radiotherapy Dosage, Photons therapeutic use, Radiometry instrumentation, Silicon

Abstract

Purpose: To investigate the effect on surface dose, as a function of different field sizes and distances from the solid water phantom to transmission detector (D sd ), of using the monolithic silicon detector MP512T in transmission mode., Methods: The influence of operating the MP512T in transmission mode on the surface dose of a phantom for SSD 100cm was evaluated by using a Markus IC. The MP512T was fixed to an adjustable stand holder and was positioned at different D sd , ranging from 0.3 to 24 cm. For each D sd , measurements were carried out for irradiation field sizes of 5 × 5cm 2 , 8 × 8 cm 2 and 10 × 10 cm 2 . Measurements were obtained under two different operational setups, (i) with the MP512T face-up and (ii) with the MP512T face-down. In addition, the transmission factors for the MP512T and the printed circuit board were only evaluated using a Farmer IC., Results: For all D sd and all field sizes, the MP512T led to the surface dose increasing by less than 25% when in the beam. For D sd >18 cm the surface dose increase is less than 5%, and negligible for field size 5 × 5 cm 2 . The difference in the surface dose perturbation for the MP512T operating face up or operating face down is negligible (<2%) for all field sizes. The transmission factor of the MP512T ranged from 1.020 to 0.9950 for all measured D sd and field sizes., Conclusion: The study demonstrated that positioning the MP512T in air between the Linac head and the phantom produced negligible perturbation of the surface dose for D sd >18 cm, and was completely transparent for 6 MV photon beams., (Copyright © 2017 Associazione Italiana di Fisica Medica. Published by Elsevier Ltd. All rights reserved.)

Published

2017

13. Development of a silicon diode detector for skin dosimetry in radiotherapy.

Author

Vicoroski N, Espinoza A, Duncan M, Oborn BM, Carolan M, Metcalfe P, Menichelli D, Perevertaylo VL, Lerch MLF, Rosenfeld AB, and Petasecca M

Subjects

Absorption, Radiation, Equipment Design, Monte Carlo Method, Radiotherapy Dosage, Electrical Equipment and Supplies, Radiometry instrumentation, Silicon, Skin radiation effects

Abstract

Purpose: The aim of in vivo skin dosimetry was to measure the absorbed dose to the skin during radiotherapy, when treatment planning calculations cannot be relied on. It is of particularly importance in hypo-fractionated stereotactic modalities, where excessive dose can lead to severe skin toxicity. Currently, commercial diodes for such applications are with water equivalent depths ranging from 0.5 to 0.8 mm. In this study, we investigate a new detector for skin dosimetry based on a silicon epitaxial diode, referred to as the skin diode., Method: The skin diode is manufactured on a thin epitaxial layer and packaged using the "drop-in" technology. It was characterized in terms of percentage depth dose, dose linearity, and dose rate dependence, and benchmarked against the Attix ionization chamber. The response of the skin diode in the build-up region of the percentage depth dose (PDD) curve of a 6 MV clinical photon beam was investigated. Geant4 radiation transport simulations were used to model the PDD in order to estimate the water equivalent measurement depth (WED) of the skin diode. Measured output factors using the skin diode were compared with the MOSkin detector and EBT3 film at 10 cm depth and at surface at isocenter of a water equivalent phantom. The intrinsic angular response of the skin diode was also quantified in charge particle equilibrium conditions (CPE) and at the surface of a solid water phantom. Finally, the radiation hardness of the skin diode up to an accumulated dose of 80 kGy using photons from a Co-60 gamma source was evaluated., Results: The PDD curve measured with the skin diode was within 0.5% agreement of the equivalent Geant4 simulated curve. When placed at the phantom surface, the WED of the skin diode was estimated to be 0.075 ± 0.005 mm from Geant4 simulations and was confirmed using the response of a corrected Attix ionization chamber placed at water equivalent depth of 0.075 mm, with the measurement agreement to within 0.3%. The output factor measurements at 10 cm depth were within 2% of those measured with film and the MOSkin detector down to a field size of 2 × 2 cm 2 . The dose-response for all detector samples was linear and with a repeatability within 0.2%. The skin diode intrinsic angular response showed a maximum deviation of 8% at 90 degrees and from 0 to 60 degree is less than 5%. The radiation sensitivity reduced by 25% after an accumulated dose of 20 kGy but after was found to stabilize. At 60 kGy total accumulated dose the response was within 2% of that measured at 20 kGy total accumulated dose., Conclusions: This work characterizes an innovative detector for in vivo and real-time skin dose measurements that is based on an epitaxial silicon diode combined with the Centre for Medical Radiation Physics (CMRP) "drop-in" packaging technology. The skin diode proved to have a water equivalent depth of measurement of 0.075 ± 0.005 mm and the ability to measure doses accurately relative to reference detectors., (© 2017 American Association of Physicists in Medicine.)

Published

2017

14. Technical Note: Angular dependence of a 2D monolithic silicon diode array for small field dosimetry.

Author

Stansook N, Utitsarn K, Petasecca M, Newall MK, Duncan M, Nitschke K, Carolan M, Metcalfe P, Lerch MLF, Perevertaylo VL, Tomé WA, and Rosenfeld AB

Subjects

Humans, Particle Accelerators, Photons, Phantoms, Imaging, Radiometry, Silicon

Abstract

Purpose: This study aims to investigate the 2D monolithic silicon diode array size of 52 × 52 mm 2 (MP512) angular response. An angular correction method has been developed that improves the accuracy of dose measurement in a small field., Methods: The MP512 was placed at the center of a cylindrical phantom, irradiated using 6 MV and 10 MV photons and incrementing the incidence of the beam angle in 15° steps from 0° to 180°, and then in 1° steps between 85° and 95°. The MP512 response was characterized for square field sizes varying between 1 × 1 cm 2 and 10 × 10 cm 2 . The angular correction factor was obtained as the ratio of MP512 response to EBT3 film measured doses as a function of the incidence angle (Ɵ) and was normalized at 0° incidence angle. Beam profiles of the corrected MP512 responses were compared with the EBT3 responses to verify the effectiveness of the method adopted., Results: The intrinsic angular dependence of the MP512 shows maximum relative deviation from the response normalized to 0° of 18.5 ± 0.5% and 15.5 ± 0.5% for 6 MV and 10 MV, respectively, demonstrating that the angular response is sensitive to the energy. In contrast, the variation of angular response is less affected by field size. Comparison of cross-plane profiles measured by the corrected MP512 and EBT3 shows an agreement within ±2% for all field sizes when the beams irradiated the array at 0°, 45°, 135°, and 180° angles of incidence from the normal to the detector plane. At 90° incidence, corresponding to a depth dose measurement, up to a 6% discrepancy was observed for a 1 × 1 cm 2 field of 6 MV., Conclusion: An angular correction factor can be adopted for small field sizes. Measurements discrepancies could be encountered when irradiating with very small fields parallel to the detector plane. Using this approach, the MP512 is shown to be a suitable detector for 2D dose mapping of small field size photon beams., (© 2017 American Association of Physicists in Medicine.)

Published

2017

15. A 2D silicon detector array for quality assurance in small field dosimetry: DUO.

Author

Shukaili KA, Petasecca M, Newall M, Espinoza A, Perevertaylo VL, Corde S, Lerch M, and Rosenfeld AB

Subjects

Quality Assurance, Health Care, Radiometry instrumentation, Silicon

Abstract

Purpose: Nowadays, there are many different applications that use small fields in radiotherapy treatments. The dosimetry of small radiation fields is not trivial due to the problems associated with lateral disequilibrium and source occlusion and requires reliable quality assurance (QA). Ideally such a QA tool should provide high spatial resolution, minimal beam perturbation and real time fast measurements. Many different types of silicon diode arrays are used for QA in radiotherapy; however, their application in small filed dosimetry is limited, in part, due to a lack of spatial resolution. The Center of Medical Radiation Physics (CMRP) has developed a new generation of a monolithic silicon diode array detector that will be useful for small field dosimetry in SRS/SRT. The objective of this study is to characterize a monolithic silicon diode array designed for dosimetry QA in SRS/SRT named DUO that is arranged as two orthogonal 1D arrays with 0.2 mm pitch., Methods: DUO is two orthogonal 1D silicon detector arrays in a monolithic crystal. Each orthogonal array contains 253 small pixels with size 0.04 × 0.8 mm 2 and three central pixels are with a size of 0.18 × 0.18 mm 2 each. The detector pitch is 0.2 mm and total active area is 52 × 52 mm 2 . The response of the DUO silicon detector was characterized in terms of dose per pulse, percentage depth dose, and spatial resolution in a radiation field incorporating high gradients. Beam profile of small fields and output factors measured on a Varian 2100EX LINAC in a 6 MV radiation fields of square dimensions and sized from 0.5 × 0.5 cm 2 to 5 × 5 cm 2 . The DUO response was compared under the same conditions with EBT3 films and an ionization chamber., Results: The DUO detector shows a dose per pulse dependence of 5% for a range of dose rates from 2.7 × 10 -4 to 1.2 × 10 -4 Gy/pulse and 23% when the rate is further reduced to 2.8 × 10 -5 Gy/pulse. The percentage depth dose measured to 25 cm depth in solid water phantom beyond the surface and for a field size of 10 × 10 cm 2 agrees with that measured using a Markus IC within 1.5%. The beam profiles in both X and Y orthogonal directions showed a good match with EBT3 film, where the FWHM agreed within 1% and penumbra widths within 0.5 mm. The effect of an air gap above the DUO detector has also been studied. The output factor for field sizes ranging from 0.5 × 0.5 cm 2 to 5 × 5 cm 2 measured by the DUO detector with a 0.5 mm air gap above silicon surface agrees with EBT3 film and MOSkin detectors within 1.8%., Conclusions: The CMRP's monolithic silicon detector array, DUO, is suitable for SRS/SRT dosimetry and QA because of its very high spatial resolution (0.2 mm) and real time operation., (© 2016 American Association of Physicists in Medicine.)

Published

2017

16. Beam perturbation characteristics of a 2D transmission silicon diode array, Magic Plate.

Author

Alrowaili ZA, Lerch ML, Petasecca M, Carolan MG, Metcalfe PE, and Rosenfeld AB

Subjects

Electrons, Humans, Photons, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Water, Magnetic Resonance Imaging instrumentation, Neoplasms radiotherapy, Particle Accelerators instrumentation, Phantoms, Imaging, Radiotherapy, Image-Guided instrumentation, Silicon chemistry

Abstract

The main objective of this study is to demonstrate the performance characteristics of the Magic Plate (MP) system when operated upstream of the patient in trans-mission mode (MPTM). The MPTM is an essential component of a real-time QA system designed for operation during radiotherapy treatment. Of particular interest is a quantitative study into the influence of the MP on the radiation beam quality at several field sizes and linear accelerator potential differences. The impact is measured through beam perturbation effects such as changes in the skin dose and/or percentage depth dose (PDD) (both in and out of field). The MP was placed in the block tray of a Varian linac head operated at 6, 10 and 18 MV beam energy. To optimize the MPTM operational setup, two conditions were investigated and each setup was compared to the case where no MP is positioned in place (i.e., open field): (i) MPTM alone and (ii) MPTM with a thin passive contamination electron filter. The in-field and out-of-field surface doses of a solid water phantom were investigated for both setups using a Markus plane parallel (Model N23343) and Attix parallel-plate, MRI model 449 ionization chambers. In addition, the effect on the 2D dose distribution measured by the Delta4 QA system was also investi-gated. The transmission factor for both of these MPTM setups in the central axis was also investigated using a Farmer ionization chamber (Model 2571A) and an Attix ionization chamber. Measurements were performed for different irradiation field sizes of 5 × 5 cm2 and 10 × 10 cm2. The change in the surface dose relative to dmax was measured to be less than 0.5% for the 6 MV, 10 MV, and 18 MV energy beams. Transmission factors measured for both set ups (i & ii above) with 6 MV, 10 MV, and 18 MV at a depth of dmax and a depth of 10 cm were all within 1.6% of open field. The impact of both the bare MPTM and the MPTM with 1 mm buildup on 3D dose distribution in comparison to the open field investigated using the Delta4 system and both the MPTM versions passed standard clinical gamma analysis criteria. Two MPTM operational setups were studied and presented in this article. The results indicate that both versions may be suitable for the new real-time megavoltage photon treatment delivery QA system under development. However, the bare MPTM appears to be slightly better suited of the two MP versions, as it minimally perturbs the radiation field and does not lead to any significant increase in skin dose to the patient.

Published

2016

17. Silicon 3D Microdosimeters for Advanced Quality Assurance in Particle Therapy.

Author

Tran, Linh T., Bolst, David, James, Benjamin, Pan, Vladimir, Vohradsky, James, Peracchi, Stefania, Chartier, Lachlan, Debrot, Emily, Guatelli, Susana, Petasecca, Marco, Lerch, Michael, Prokopovich, Dale, Pastuović, Željko, Povoli, Marco, Kok, Angela, Inaniwa, Taku, Lee, Sung Hyun, Matsufuji, Naruhiro, and Rosenfeld, Anatoly B.

Subjects

MEDICAL physics, PROTON beams, QUALITY assurance, ELECTRONIC equipment enclosures, SILICON, TISSUE arrays

Abstract

The Centre for Medical Radiation Physics introduced the concept of Silicon On Insulator (SOI) microdosimeters with 3-Dimensional (3D) cylindrical sensitive volumes (SVs) mimicking the dimensions of cells in an array. Several designs of high-definition 3D SVs fabricated using 3D MEMS technology were implemented. 3D SVs were fabricated in different sizes and configurations with diameters between 18 and 30 µm, thicknesses of 2–50 µm and at a pitch of 50 µm in matrices with volumes of 20 × 20 and 50 × 50. SVs were segmented into sub-arrays to reduce capacitance and avoid pile up in high-dose rate pencil beam scanning applications. Detailed TCAD simulations and charge collection studies in individual SVs have been performed. The microdosimetry probe (MicroPlus) is composed of the silicon microdosimeter and low-noise front–end readout electronics housed in a PMMA waterproof sheath that allows measurements of lineal energies as low as 0.4 keV/µm in water or PMMA. Microdosimetric quantities measured with SOI microdosimeters and the MicroPlus probe were used to evaluate the relative biological effectiveness (RBE) of heavy ions and protons delivered by pencil-beam scanning and passive scattering systems in different particle therapy centres. The 3D detectors and MicroPlus probe developed for microdosimetry have the potential to provide confidence in the delivery of RBE optimized particle therapy when introduced into routine clinical practice. [ABSTRACT FROM AUTHOR]

Published

2022

18. SOI Thin Microdosimeters for High LET Single-Event Upset Studies in Fe, O, Xe, and Cocktail Ion Beam Fields.

Author

James, Benjamin, Povoli, Marco, Kok, Angela, Goethem, Marc-Jan, Nancarrow, Mitchell, Matsufuji, Naruhiro, Jackson, Michael, Rosenfeld, Anatoly B., Tran, Linh T., Bolst, David, Peracchi, Stefania, Davis, Jeremy A., Prokopovich, Dale A., Guatelli, Susanna, Petasecca, Marco, and Lerch, Michael

Subjects

ION bombardment, LINEAR energy transfer, LATTICE constants

Abstract

The response of a 5-μm-thin silicon on insulator (SOI) 3-D microdosimeter was investigated for single-event upset applications by measuring the linear energy transfer (LET) of different high LET ions. The charge collection characteristics of the device were performed using the ion beam-induced charge collection (IBIC) technique with 3- and 5.5-MeV He2+ ions incident on the microdosimeter. The microdosimeter was irradiated with 16O, 56Fe, and 124Xe ions and was able to determine the LET within 5% for most configurations apart from 124Xe. It was observed that on average, measured LET was 12% lower for 30-MeV/u 124Xe ion traversing through different thickness Kapton absorbers in comparison to Geant4 simulations. This discrepancy can be partly attributed to uncertainties in the thickness of the energy degraders and the thickness of the SOI layer of the devices. The effects of overlayer thickness variation are not easily observed for ions with much lower LET as O and Fe. Based on that, it is difficult to make conclusion that the plasma effect is observed for 30-MeV/u124Xe ions and further research to be carried out for ion with LET higher than 12 MeV/μm. [ABSTRACT FROM AUTHOR]

Published

2020

19. SOI Thin Microdosimeter Detectors for Low-Energy Ions and Radiation Damage Studies.

Author

James, Benjamin, Tran, Linh T., Vohradsky, James, Bolst, David, Pan, Vladimir, Carr, Madeline, Guatelli, Susanna, Pogossov, Alex, Petasecca, Marco, Lerch, Michael, Prokopovich, Dale A., Reinhard, Mark I., Povoli, Marco, Kok, Angela, Hinde, David, Dasgupta, Mahananda, Stuchbery, Andrew, Perevertaylo, Vladimir, and Rosenfeld, Anatoly B.

Subjects

DOSIMETERS, SILICON-on-insulator technology, MEDICAL physics, LINEAR energy transfer, PLASMA physics

Abstract

The responses of two silicon on insulator (SOI) 3-D microdosimeters developed by the Centre for Medical Radiation Physics were investigated with a range of different low energy ions, with high linear energy transfer (LET). The two microdosimeters n-SOI and p-SOI were able to measure the LET of different ions including 7Li, 12C, 16O, and 48Ti with ranges below $350~\mu \text{m}$ in silicon. No plasma effects were seen in the SOI microdosimeters when irradiated with the high LET ions. A Monte Carlo simulation using Geant4 was compared to the experimental measurements, whereby some discrepancies were observed for heavier ions at lower energies. This discrepancy can be partly attributed to uncertainties in the thickness of the energy degraders and overlayers of the devices. The microdosimetric measurements of low energy 16O ions were obtained and compared to a therapeutic 16O ion beam. The radiation hardness of the two devices was studied using the ion beam induced charge collection technique. Both types of the microdosimeters when biased had no essential changes in charge collection efficiency in the sensitive volume after irradiation with low energy ions. [ABSTRACT FROM AUTHOR]

Published

2019

20. On the Instantaneous Dose Rate and Angular Dependence of Monolithic Silicon Array Detectors.

Author

Biasi, Giordano, Hardcastle, Nicholas, Petasecca, Marco, Guatelli, Susanna, Perevertaylo, Vladimir, Kron, Tomas, and Rosenfeld, Anatoly B.

Subjects

MONOLITHIC reactors, RADIOTHERAPY, RADIATION dosimetry, QUALITY assurance, SILICON

Abstract

The use of small radiation fields characterized by very steep dose gradients is common in modulated arc X-ray radiotherapy. Dosimeters for quality assurance (QA) applications would ideally have sensitive volumes (SVs) relatively small with respect to the field, along with negligible instantaneous dose rate and angular dependence. Silicon-based dosimeters can be fabricated with SVs $ < 100~\mu \text {m}$ across, provide a stable and near energy-independent response in megavoltage photon beams, along with a good linearity with accumulated dose and real-time readout. However, their sensitivity is instantaneous dose rate and angular dependent. Monolithic silicon array detectors with sufficiently small SVs and pitch are suitable for high-resolution 2-D dose mapping in radiation fields with steep dose gradients. The Octa is a 2-D monolithic silicon array detector. It has 512 diode- SVs arranged with a sub-millimeter pitch. The physical characteristics of the substrate on which it is based, in terms of resistivity and defects concentration, strongly affect its performance. We report on the experimental characterization of two versions of the Octa, manufactured on a bulk and on an epitaxial substrate, respectively. Their performance is compared and discussed in terms of their instantaneous dose rate and angular dependence in the context of QA applications in small radiation fields delivered with modulated arc radiotherapy. [ABSTRACT FROM AUTHOR]

Published

2019

21. On Monolithic Silicon Array Detectors for Small-Field Photon Beam Dosimetry.

Author

Biasi, Giordano, Davis, Jeremy, Petasecca, Marco, Guatelli, Susanna, Perevertaylo, Vladimir, Kron, Tomas, and Rosenfeld, Anatoly B.

Subjects

SILICON wafers, RADIATION dosimetry, PHOTON beams, SUBSTRATES (Materials science), COLLIMATORS

Abstract

Contemporary x-ray radiotherapy employs small radiation fields to deliver highly conformal dose distributions. Submillimeter accuracy in the measurement of the delivered dose map is a crucial requirement of detectors proposed for quality assurance applications. A 2-D monolithic silicon array detector can provide high spatial resolution by optimizing small sensitive volumes (SVs) in a large active area. They offer a stable and near energy-independent response in megavoltage photon beams, good dose linearity, and real-time read-out. The SVs are ion-implanted on a silicon wafer whose geometry and physical characteristics, such as resistivity and defects concentration, dramatically affect the detector performance. The Octa is a novel 2-D monolithic silicon array detector dedicated to small-field dosimetry. Its 512 diode SVs are arranged with a submillimeter pitch along four intersecting orthogonal linear arrays. We report on the experimental and numerical characterization (performed with Sentaurus Workbench within the Synopsys framework) of two Octa detectors manufactured, respectively, on a bulk and on an epitaxial silicon substrate. The effects of resistivity and defects concentration profiles across their large-area monolithic silicon wafers are compared and discussed in terms of the response linearity with dose, response uniformity, charge-collection efficiency, and clinical performance in the case of a small radiation field delivered with a flattening filter-free beam. [ABSTRACT FROM AUTHOR]

Published

2018

22. Thin Silicon Microdosimeter Utilizing 3-D MEMS Fabrication Technology: Charge Collection Study and Its Application in Mixed Radiation Fields.

Author

Tran, Linh T., Chartier, Lachlan, Prokopovich, Dale A., Bolst, David, Povoli, Marco, Summanwar, Anand, Kok, Angela, Pogossov, Alex, Petasecca, Marco, Guatelli, Susanna, Reinhard, Mark I., Lerch, Michael, Nancarrow, Mitchell, Matsufuji, Naruhiro, Jackson, Michael, and Rosenfeld, Anatoly B.

Subjects

DOSIMETERS, HEAVY ions, NUCLEAR counters, SILICON, MEDICAL technology, ELECTRONS

Abstract

New 10- \mu \textm -thick silicon microdosimeters utilizing 3-D technology have been developed and investigated in this paper. The TCAD simulations were carried out to understand the electrical properties of the microdosimeters’ design. A charge collection study of the devices was performed using 5.5-MeV He2+ ions which were raster scanned over the surface of the detectors and the charge collection median energy maps were obtained and the detection yield was also evaluated. The devices were tested in a 290 MeV/u carbon ion beam at the Heavy Ion Medical Accelerator in Chiba (HIMAC) in Japan. Based on the microdosimetric measurements, the quality factor and dose equivalent out of field were obtained in a mixed radiation field mimicking the radiation environment for spacecraft in deep space. [ABSTRACT FROM PUBLISHER]

Published

2018

23. Characterisation of Silicon Diode Arrays for Dosimetry in External Beam Radiation Therapy.

Author

Porumb, Claudiu S., Aldosari, Abdullah H., Fuduli, Iolanda, Cutajar, Dean, Newall, Matthew, Metcalfe, Peter, Carolan, Martin, Lerch, Michael L. F., Perevertaylo, Vladimir L., Rosenfeld, Anatoly B., and Petasecca, Marco

Subjects

STEREOTACTIC radiotherapy, NUCLEAR counters, SILICON detectors, MICROPROBE analysis, PHOTONS

Abstract

Modern stereotactic radiation therapy modalities utilize small beams and large dose gradients to deliver radiation in few fractions, reducing the possibility to correct for mistakes during the treatment process. Therefore, in order to ensure best possible treatment for the patient, quality assurance for such treatments necessitates a stable, linear, and sensitive radiation detector with high spatial resolution and radiation hardness. In this work, two silicon detector arrays with high spatial resolution have been characterized by 6 MV and 18 MV medical LINAC irradiation, and 5.5 MeV He2+ heavy ion microprobe. A maximum discrepancy of 0.6 mm in field size has been found when comparing to two-dimensional radiochromic film dose profile, and charge collection efficiency obtained by means of ion beam induced charge collection (IBICC) is 66% when operating the array in photovoltaic mode. Radiation damage study by photons and photoneutrons is presented. [ABSTRACT FROM PUBLISHER]

Published

2016

24. 3D-Mesa “Bridge” Silicon Microdosimeter: Charge Collection Study and Application to RBE Studies in ^12C Radiation Therapy.

Author

Tran, Linh T., Chartier, Lachlan, Prokopovich, Dale A., Reinhard, Mark I., Petasecca, Marco, Guatelli, Susanna, Lerch, Michael L. F., Perevertaylo, Vladimir L., Zaider, Marco, Matsufuji, Naruhiro, Jackson, Michael, Nancarrow, Mitchell, and Rosenfeld, Anatoly B.

Subjects

MICRODOSIMETRY, HADRONS, RADIATION dosimetry, MICROPROBE analysis, MICROCHEMISTRY

Abstract

Microdosimetry is an extremely useful technique, used for dosimetry in unknown mixed radiation fields typical of space and aviation, as well as in hadron therapy. A new silicon microdosimeter with 3D sensitive volumes has been proposed to overcome the shortcomings of the conventional Tissue Equivalent Proportional Counter. In this article, the charge collection characteristics of a new 3D mesa microdosimeter were investigated using the ANSTO heavy ion microprobe utilizing 5.5 MeV He^2 + and 2 MeV H^ + ions. Measurement of the microdosimetric characteristics allowed for the determination of the Relative Biological Effectiveness of the ^12C heavy ion therapy beam at the Heavy Ion Medical Accelerator in Chiba (HIMAC), Japan. Well-defined sensitive volumes of the 3D mesa microdosimeter have been observed and the microdosimetric RBE obtained showed good agreement with the TEPC. The new 3D mesa “bridge” microdosimeter is a step forward towards a microdosimeter with fully free-standing 3D sensitive volumes. [ABSTRACT FROM PUBLISHER]

Published

2015

25. 3D Radiation Detectors: Charge Collection Characterisation and Applicability of Technology for Microdosimetry.

Author

Tran, Linh T., Prokopovich, Dale A., Petasecca, Marco, Lerch, Michael L. F., Kok, Angela, Summanwar, Anand, Hansen, Thor-Erik, Via, Cinzia Da, Reinhard, Mark I., and Rosenfeld, Anatoly B.

Subjects

NUCLEAR counters, SILICON detectors, MICRODOSIMETRY, ION beams, THREE-dimensional display systems

Abstract

A study of charge collection in SINTEF 3D active edge silicon detectors was carried out at ANSTO using Ion Beam Induced Charge (IBIC) technique. An IBIC study has shown that several different geometries of 3D detectors have full depletion under low applied bias. The effect of fast neutron and gamma radiation on their charge collection efficiency was also investigated. A 3D active edge silicon detector technology has demonstrated extremely promising performance for application of the 3D Sensitive Volumes (SVs) fabrication methods to SOI microdosimetry. [ABSTRACT FROM PUBLISHER]

Published

2014

26. Tissue Equivalence Study of a Novel Diamond-Based Microdosimeter for Galactic Cosmic Rays and Solar Particle Events.

Author

Davis, Jeremy A., Guatelli, Susanna, Petasecca, Marco, Lerch, Michael L. F., Reinhard, Mark I., Zaider, Marco, Ziegler, James, and Rosenfeld, Anatoly B.

Subjects

GALACTIC cosmic rays, NUCLEAR counters, MICRODOSIMETRY, DIAMONDS, ALPHA rays

Abstract

Radiation detectors based on diamond are attractive for radiation protection applications in space and aviation due to their radiation hardness, large breakdown voltage, fast signal collection, and low noise, thus representing a valid alternative to silicon-based detector devices. In this paper, we study the tissue equivalence of diamond in proton and \alpha particle radiation fields typical of galactic cosmic rays and solar particle events. We determine a method to convert microdosimetric response from diamond to water by means of Geant4 simulations. Results are presented showing that a simple geometrical scaling factor (\sim 0.32) of linear dimensions is adequate to convert experimentally obtained microdosimetric energy deposition spectra in diamond to equivalent microdosimetric energy deposition spectra in water. [ABSTRACT FROM PUBLISHER]

Published

2014

27. A Novel Silicon Microdosimeter Using 3D Sensitive Volumes: Modeling the Response in Neutron Fields Typical of Aviation.

Author

Tran, Linh T., Guatelli, Susanna, Prokopovich, Dale A., Petasecca, Marco, Lerch, Michael L. F., Reinhard, Mark I., Ziegler, James F., Zaider, Marco, and Rosenfeld, Anatoly B.

Subjects

MICRODOSIMETRY, SILICON research, NEUTRONS, POLYMETHYLMETHACRYLATE, MEDICAL physics

Abstract

A 4th generation silicon microdosimeter has been designed by the Centre for Medical Radiation Physics (CMRP) at the University of Wollongong using three dimensional (3D) Sensitive Volumes (SVs). This new microdosimeter design has the advantage of well-defined 3D SVs as well as the elimination of lateral charge diffusion by removal of silicon laterally adjacent to the 3D SVs. The gaps between the sensitive volumes are to be backfilled with PolyMethyl MethAcrylate (PMMA) to produce a surrounding tissue equivalent medium. The advantage of this design avoids the generation of secondary particles from inactive silicon lateral to SVs. The response of the microdosimeter to the neutron field from ^252Cf, Pu-Be sources and an avionic radiation environment were simulated using the Geant4 Monte Carlo toolkit for design optimisation. The simulated energy deposition in the SVs from the neutron fields and microdosimetric spectra is presented. The simulation study shows a significant reduction in silicon nuclear recoil contribution to the energy deposition for the novel microdosimeter design. The reduction of silicon recoil events from outside of the SV’s will consequently reduce the uncertainty in the calculated dose equivalent. The simulations have demonstrated that a 3D silicon microdosimeter surrounded by PMMA can produce microdosimetric spectra similar to those of a tissue equivalent microdosimeter. [ABSTRACT FROM PUBLISHER]

Published

2014