Your search keyword '"Crowe, S. B."' showing total 4 results

1. A very low diffusion Fricke gel dosimeter with functionalised xylenol orange-PVA (XOPVA)

Author

Smith, S T, primary, Boase, N R B, additional, Masters, K-S, additional, Hosokawa, K, additional, Asena, A, additional, Crowe, S B, additional, Kairn, T, additional, and Trapp, J V, additional

Published

2019

2. Monte Carlo-based diode design for correction-less small field dosimetry.

Author

Charles, P. H., Crowe, S. B., Kairn, T., Knight, R. T., Hill, B., Kenny, J., Langton, C. M., and Trapp, J. V.

Subjects

*DIODES, *RADIATION dosimetry, *MONTE Carlo method, *PHOTONS, *SILICON

Abstract

Due to their small collecting volume, diodes are commonly used in small field dosimetry. However, the relative sensitivity of a diode increases with decreasing small field size. Conversely, small air gaps have been shown to cause a significant decrease in the sensitivity of a detector as the field size is decreased. Therefore, this study uses Monte Carlo simulations to look at introducing air upstream to diodes such that they measure with a constant sensitivity across all field sizes in small field dosimetry. Varying thicknesses of air were introduced onto the upstream end of two commercial diodes (PTW 60016 photon diode and PTW 60017 electron diode), as well as a theoretical unenclosed silicon chip using field sizes as small as 5 mm × 5 mm. The metric Dw,Q/DDet,Q used in this study represents the ratio of the dose to a point of water to the dose to the diode active volume, for a particular field size and location. The optimal thickness of air required to provide a constant sensitivity across all small field sizes was found by plotting Dw,Q/DDet,Q as a function of introduced air gap size for various field sizes, and finding the intersection point of these plots. That is, the point at which Dw,Q/DDet,Q was constant for all field sizes was found. The optimal thickness of air was calculated to be 3.3, 1.15 and 0.10 mm for the photon diode, electron diode and unenclosed silicon chip, respectively. The variation in these results was due to the different design of each detector. When calculated with the new diode design incorporating the upstream air gap, k fclin, fmsr Qclin,Qmsr was equal to unity to within statistical uncertainty (0.5%) for all three diodes. Cross-axis profilemeasurements were also improved with the new detector design. The upstream air gap could be implanted on the commercial diodes via a cap consisting of the air cavity surrounded by water equivalent material. The results for the unclosed silicon chip show that an ideal small field dosimetry diode could be created by using a silicon chip with a small amount of air above it [ABSTRACT FROM AUTHOR]

Published

2013

3. The effect of very small air gaps on small field dosimetry.

Author

Charles, P. H., Crowe, S. B., Kairn, T., Kenny, J., Lehmann, J., Lye, J., Dunn, L., Hill, B., Knight, R. T., Langton, C. M., and Trapp, J. V.

Subjects

*RADIATION dosimetry, *STEREOTAXIC techniques, *LINEAR accelerators, *MONTE Carlo method, *DETECTORS, *LUMINESCENCE, *IMAGING phantoms

Abstract

The purpose of this study was to investigate the effect of very small air gaps (less than 1 mm) on the dosimetry of small photon fields used for stereotactic treatments. Measurements were performed with optically stimulated luminescent dosimeters (OSLDs) for 6 MV photons on a Varian 21iX linear accelerator with a Brainlab µMLC attachment for square field sizes down to 6 mm × 6 mm. Monte Carlo simulations were performed using EGSnrc C++ user code cavity. It was found that the Monte Carlo model used in this study accurately simulated the OSLD measurements on the linear accelerator. For the 6 mm field size, the 0.5 mm air gap upstream to the active area of the OSLD caused a 5.3% dose reduction relative to a Monte Carlo simulation with no air gap. A hypothetical 0.2 mm air gap caused a dose reduction >2%, emphasizing the fact that even the tiniest air gaps can cause a large reduction in measured dose. The negligible effect on an 18 mm field size illustrated that the electronic disequilibrium caused by such small air gaps only affects the dosimetry of the very small fields. When performing small field dosimetry, care must be taken to avoid any air gaps, as can be often present when inserting detectors into solid phantoms. It is recommended that very small field dosimetry is performed in liquid water. When using small photon fields, sub-millimetre air gaps can also affect patient dosimetry if they cannot be spatially resolved on a CT scan. However the effect on the patient is debatable as the dose reduction caused by a 1 mm air gap, starting out at 19% in the first 0.1 mm behind the air gap, decreases to <5% after just 2 mm, and electronic equilibrium is fully re-established after just 5 mm. [ABSTRACT FROM AUTHOR]

Published

2012

4. Monte Carlo verification of gel dosimetry measurements for stereotactic radiotherapy.

Author

Kairn, T., Taylor, M. L., Crowe, S. B., Dunn, L., Franich, R. D., Kenny, J., Knight, R. T., and Trapp, J. V.

Subjects

MONTE Carlo method, RADIATION dosimetry, STEREOTAXIC techniques, RADIOTHERAPY, RADIOSURGERY, SIMULATION methods & models, COMPARATIVE studies

Abstract

The quality assurance of stereotactic radiotherapy and radiosurgery treatments requires the use of small-field dose measurements that can be experimentally challenging. This study used Monte Carlo simulations to establish that PAGAT dosimetry gel can be used to provide accurate, high-resolution, three-dimensional dose measurements of stereotactic radiotherapy fields. A small cylindrical container (4 cm height, 4.2 cm diameter) was filled with PAGAT gel, placed in the parietal region inside a CIRS head phantom and irradiated with a 12-field stereotactic radiotherapy plan. The resulting threedimensional dose measurement was read out using an optical CT scanner and compared with the treatment planning prediction of the dose delivered to the gel during the treatment. A BEAMnrc/DOSXYZnrc simulation of this treatment was completed, to provide a standard against which the accuracy of the gel measurement could be gauged. The three-dimensional dose distributions obtained from Monte Carlo and from the gel measurement were found to be in better agreement with each other than with the dose distribution provided by the treatment planning system's pencil beam calculation. Both sets of data showed close agreement with the treatment planning system's dose distribution through the centre of the irradiated volume and substantial disagreement with the treatment planning system at the penumbrae. The Monte Carlo calculations and gel measurements both indicated that the treated volume was up to 3 mm narrower, with steeper penumbrae and more variable out-of-field dose, than predicted by the treatment planning system. The Monte Carlo simulations allowed the accuracy of the PAGAT gel dosimeter to be verified in this case, allowing PAGAT gel to be utilized in themeasurement of dose from stereotactic and other radiotherapy treatments, with greater confidence in the future. [ABSTRACT FROM AUTHOR]

Published

2012