Licensable Power Capacity of the PUR-1 Research Reactor

Clive Townsend (6081273)

03 January 2019

This work aims to develop a theoretical power operations envelope for the PUR-1 reactor. Given the bulk coolant temperature, the reactor’s power level is limited primarily by the Onset of Nucleate Boiling. Additional limitations to the reactor power are explored including the dose rate at the top of the pool due to shine and the airborne effluent of argon and nitrogen. Operations in excess of the facility cooling capacity will be proposed and are already permitted at other US research reactor facilities, provided temperature limitations are met. The MCNP and NATCON code packages have been implemented to assist in power limitation measurement. A brief discussion on the licensing considerations is included to provide some framework for pursuit of these higher power levels. The maximum power consideration ensures continued full use of the facility while maximizing its effectiveness in the teaching laboratories and access to researchers. The final power level is limited by the administrative dose limit at the top of the reactor pool as well as the Onset of Nucleate Boiling power level as a function of bulk pool temperature. The result is an operational envelope which would allow operators to have the maximum neutron flux without changing the facility or creating phase transition within the light water coolant.

Nuclear Engineering

power uprate

natural convection

neutonics

radiation dose

research reactor

Computed tomography imaging of the heart

Williams, Michelle Claire

January 2016

Computed tomography imaging has revolutionised modern medicine and we can now study the body in greater detail than ever before. Cardiac computed tomography has the potential to provide information not just on coronary anatomy, but also on myocardial function, perfusion and viability. This thesis addresses the optimisation and validation of computed tomography imaging of the heart using a wide volume 320-multidetector scanner. Computed tomography coronary angiography now has diagnostic accuracy comparable to invasive coronary angiography. However, radiation dose remains an important concern. It is therefore important to minimise computed tomography radiation dose while maintaining image quality. I was able to demonstrate that iterative reconstruction and patient tailored imaging techniques led to a 39% reduction in radiation dose in computed tomography coronary angiography, while maintaining subjective and objective assessments of image quality. In addition, I demonstrated that diagnostic images can be obtained in 99% of unselected patients presenting with suspected coronary artery disease when using single heart-beat 320- multidetector computed tomography coronary angiography. Computed tomography myocardial perfusion imaging can provide additional and complementary information as compared to computed tomography coronary angiography that can aid diagnosis and management. I established both quantitative and qualitative assessment of computed tomography myocardial perfusion imaging and validated it against both a clinical “gold-standard”, fractional flow reserve during invasive coronary angiography, and a physiological “gold-standard”, positron emission tomography with oxygen-15 labelled water. Finally, I was able to show that techniques to reduce radiation dose can also be applied to computed tomography myocardial perfusion imaging, leading to a 60% reduction in radiation dose, while maintaining image quality. In my thesis, I have established that comprehensive cardiac angiographic and perfusion imaging can be performed with wide volume computed tomography in a broad generalizable population of patients with relatively low radiation exposure. These techniques provide both structural and functional assessments from a single imaging modality that are valid and readily applicable to the clinic in the assessment and management of patients with suspected coronary artery disease.

Towards an optimized low radiation dose quantitative computed tomography protocol for pulmonary airway assessment

Judisch, Alexandra Lynae

01 May 2015

Lung disease affects tens of millions of Americans, making it one of the most common medical conditions in the United States. Many of these lung diseases are classified as chronic airway disease. Because of this, it is important to be able to catch the development early so as to begin treatment as soon as possible to delay the progression and subsequently monitor that progression. One method of doing so is the use of quantitative computed tomography (CT). Study of the airway anatomy can be quantified using such measures as minor inner diameter (MinD), major inner diameter (MajD), wall thickness (WT), inner area (IA), and outer area (OA). Changes in these measures can then be tracked over time to determine how the airways are being affected by disease. The challenge with the desired longitudinal imaging is that prolonged radiation exposure can be dangerous to the patient. In order to make longitudinal imaging more feasible, it is important to determine what quantitative measures can reliably be made at different radiations doses so as to optimize radiation dose and quantitative assessment. Working to make this determination, three different radiation doses were tested to evaluate their quantitative outputs. A high dose (14.98 mGy), medium dose (6.00), and low dose (0.74 mGy) were used to image six different porcine subjects. Images were collected at these doses both while the lungs were in-vivo and once the lungs had been fixed and excised ex-vivo. All of the scans were then processed using APOLLO (VIDA Diagnostics). From the complete airway trees, quantitative measures were collected from thirty-five airways. For the whole lung analysis, the medium and low dose in-vivo scans and the high dose ex-vivo scans were compared to the high dose in-vivo scans to compare assess MinD, MajD, WT, IA, and OA. Then, in order to determine how well the CT measures represent the actual anatomy, a total of thirteen cube samples containing airways were segmented from one of the lungs (based on volume analysis of the lung pre- and post-fixation and visual inspection). The cubes were imaged in CT, for the purpose of aiding in the establishment of original location and studying the effect of a narrowed imaging window, and microscopic CT (μCT). Since μCT can have a resolution on the scale of microns, the values measured in these images were considered ground-truth. The CT and μCT cubes were then registered to the high dose ex-vivo scan so as to compare the cube values with the ex-vivo values from each of the three doses. The same five measures were collected and analyzed. The MinD, MajD, WT, IA, OA were statistically analyzed between the three in-vivo radiation dose scan sets, the high dose in- and ex-vivo scans, and the µCT cube, CT cube, and the three ex-vivo radiation dose sets. Preliminary results for the in-vivo scans show that the low dose and medium dose scans can reliably (< 5% error) be used to evaluate airways with minor diameters between 3.42 mm and 10.34 mm and major diameters between 3.98 mm and 12.06 mm. Comparison of the high-dose in-vivo and ex-vivo scans showed that the fixation and excision of the lungs did not significantly affect the ex-vivo lungs' ability to be used as a model for the in-vivo lungs. Finally, analysis of the various forms of the ex-vivo airways showed that there were few statistically significant differences between the datasets. These results support the use of using the low (0.74 mGy) radiation dose when studying airway disease affecting airways with minor diameters between 3.42 mm and 10.34 mm and major diameters between 3.98 mm and 12.06 mm. They also show that the quantitative measures from CT are representative of the true measures of the airways.

publicabstract

CT

FWHM

lung disease

radiation dose

registration

Lateral electron disequilibrium in radiation therapy

Chan, Kin Wa (Karl), University of Western Sydney, College of Science, Technology and Environment, School of Computing and Information Technology

January 2002

The radiation dose in radiation therapy is mainly measured by ion chamber. The ion chamber measurement will not be accurate if there is not enough phantom material surrounding the ion chamber to provide the electron equilibrium condition. The lack of electron equilibrium will cause a reduction of dose. This may introduce problems in treatment planning. Because some planning algorithms cannot predict the reduction, they over estimate the dose in the region. Electron disequilibrium will happen when the radiation field size is too small or the density of irradiated material is too low to provide sufficient electrons going into the dose volume. The amount of tissue required to provide electron equilibrium in a 6MV photon beam by three methods: direct calculation from Klein-Nisina equation, measurement in low density material phantom and a Monte Carlo simulation is done to compare with the measurement, an indirect method from a planning algorithm which does not provide an accurate result under lateral electron disequilibrium. When the error starts to happen in such planning algorithm, we know that the electron equilibrium conditions does not exist. Only the 6MV photon beam is investigated. This is because in most cases, a 6MV small fields are used for head and neck (larynx cavity) and 6MV fields are commonly used for lung to minimise uncertainity due to lateral electron at higher energies. / Master of Science (Hons)

radiation dose

radiation therapy

ion chamber

phantom material

measurement

Klein-Nisina equation

Novel Methods for Reducing Breast Dose During Computed Tomography Scans

January 2011

Pediatric female and young adult female patients who undergo computed tomography (CT) scanning may be at higher risk for developing radiation-induced breast cancer later in life. Thus, the purpose of this thesis was to both accurately quantify dose and explore new strategies for CT breast dose reduction. In order to determine dose reduction, dose quantification was first assessed through the development and validation of an empirical model for describing attenuation in CT and second through evaluation of the precision of dosimetry-related measurements obtained using three different models of CT scanners. Breast dose-savings was evaluated using CT dose index phantoms, anthropomorphic phantoms, and Monte Carlo computer modeling. Modifications to current scanning procedures, such as proper patient centering and beginning data acquisition with the x-ray tube facing a patient's posterior, were shown to minimize breast dose. Novel techniques, including varying the x-ray tube voltage during scanning and incorporation of a dynamic x-ray beam filter over the breasts, were also found to successfully reduce breast dose.

Health and environmental sciences

Applied sciences

Radiation dose

CT scanning

Biomedical engineering

Medical imaging

Dosimetria de filtros dinamicos aprimorados

SILVA, ROSIANE A. da

09 October 2014

Made available in DSpace on 2014-10-09T12:51:10Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T13:56:23Z (GMT). No. of bitstreams: 0 / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN/CNEN-SP

DOSIMETERS

IONIZATION CHAMBERS

RADIATION DOSE DISTRIBUTIONS

DATA ACQUISITION SYSTEMS

DOSIMETRY

EXPERIMENTAL DATA

Otimização de protocolos de abdômen-pelve em tomografia computadorizada multislice utilizando associações de avaliações subjetivas e objetivas

Maués, Nadine Helena Pelegrino Bastos.

January 2017

Orientador: Diana Rodrigues de Pina / Resumo: A tomografia computadorizada (TC) é amplamente utilizada no diagnóstico e estadiamento de patologias da região de abdômen-pelve devido a sua alta sensibilidade e especificidade. A possibilidade de adquirir maior número de imagens em menor tempo e a maior disponibilidade de equipamentos levaram a um aumento significativo dos exames de TC e consequente aumento das doses efetivas globais fornecidas por esta modalidade. Desta forma, foram desenvolvidas ferramentas que buscam reduzir as doses de radiação dos exames sem perda da qualidade da imagem. Uma destas ferramentas é a modulação automática da corrente do tubo (automatic tube current modulation – ATCM), que permite a obtenção de exames que concordam com o princípio ALARA (as low as reasonably achievable). O objetivo deste estudo foi avaliar a qualidade da imagem e as doses de radiação de diferentes protocolos de TC de abdômen-pelve com a ferramenta ATCM. Foram avaliados cinco protocolos de TC de abdômen-pelve com a ferramenta ATCM em dois tomógrafos distintos, um 16-canais e um 64 canais. Foi utilizado um fantoma antropomórfico para avaliações dosimétricas e um fantoma analítico para avaliações objetivas de qualidade da imagem. Para a análise subjetiva da qualidade da imagem, foram utilizados 15 exames retrospectivos de pacientes submetidos a TC de abdômen-pelve. Estes exames foram avaliados por um radiologista com experiência na área de tomografia de abdômen. As três análises forneceram informações que possibilitaram a escol... (Resumo completo, clicar acesso eletrônico abaixo) / Mestre

Tomografia.

Corrente modulada

Dose de radiação

Redução de dose

Computed tomography

Dose reduction

Radiation dose

Tube current modulation

Estimating patient peak skin dose with fluoroscopic procedures

Hellström, Max

January 2018

During image guided interventional radiology (IR) procedures, acute X-ray induced skin injuries may occur due to high absorbed patient skin dose. These procedures are highly dependent on X-ray imaging both for guiding fluoroscopy and high quality diagnostic image acquisitions. A dose metric that quantifies the peak absorbed skin dose (PSD) is therefore of great importance, both in terms of patient specific follow-up and for imaging protocol optimization. Presently, the cumulative interventional reference point (IRP) air Kerma is the most common skin dose estimation metric in use. This metric lacks several important dose contributions, such as pre-patient attenuation, air-to-skin medium correction, scattering from the patient and the support table, and fluence correction for actual source-to-skin distance. In this manuscript, we present a novel methodology for estimating the maximum absorbed skin dose by using dose related X-ray equipment parameters, such as peak tube voltage, support table position and IRP air Kerma obtained from radiation dose structured reports (RDSR) generated by modern IR equipment. In particular, Siemens Artis Zee (Siemens Healthineers, Erlangen, Germany) and Philips Allura Clarity (Philips, Amsterdam, Netherlands). The calculation process was automated by the development of a series of programming scripts in the PythonTM programming language v3.6 (Python Software Foundation), together with a database storing correction factors and machine specific parameters such as half-value layer (HVL). The proposed calculation model enables the implementation of a dose metric which corresponds better to absorbed skin dose than IRP air Kerma in clinical settings. However, extensive future work is required for a complete PSD implementation, in particular, the development of a skin dose map in which the spatial location of each irradiation event is tracked.

skin dose

radiation dose structured reports

interventional radiology

radiation dosimetry

Other Natural Sciences

Annan naturvetenskap

Desenvolvimento e caracterização de um gel alanima para aplicação na medida da distribuição da dose de radiação usando a técnica de espectrofotometria

MIZUNO, ERICK Y.

09 October 2014

Made available in DSpace on 2014-10-09T12:53:23Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T13:58:12Z (GMT). No. of bitstreams: 0 / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energéticas e Nucleares - IPEN-CNEN/SP

DOSIMETERS

COBALT 60

GAMMA RADIATION

RADIATION DOSE DISTRIBUTIONS

RADIOTHERAPY

GELS

ALAMINES

SPECTROTHOTOMETRY

MAGNETIC RESONANCE

Desenvolvimento de um sistema de dosimetria in vivo por meio de filmes portals para o controle da qualidade de tratamentos radioterapeuticos

FERAUCHE, DEBORA C.

09 October 2014

Made available in DSpace on 2014-10-09T12:46:49Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T13:58:28Z (GMT). No. of bitstreams: 0 / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN/CNEN-SP

radiotherapy

dosimetry

in vivo

film dosimetry

quality control

radiation dose distributions

isodose curves