Global ETD Search

101	Techniques for thermoluminescent glow-curve analysis and the dose response of individual glow peaks in '7LiF Perks, Christopher A. January 1991 (has links) No description available. 571.45 Radiobiology & radiation biology
102	The synthesis of metabolic tracers covalently labelled with short-lived radionuclides Goulding, Ronald William January 1981 (has links) No description available. 571.45 Radiobiology & radiation biology
103	The prediction and measurement of microdosimetric spectra relating to neutron cancer therapy Taylor, Graeme C. January 1990 (has links) No description available. 571.45 Radiobiology & radiation biology
104	Development of a biokinetic-dosimetric model for '2'1'0Pb and '2'1'0Po based on alpha spectroscopic measurements of '2'1'0Po in bone : methodological issues and biological implications Salmon, Philip Linley January 1998 (has links) No description available. 539.7
105	Dosimetric and Radiobiological Comparison of the Effects of High Definition versus Normal Collimation on Treatment Plans for Stereotactic Lung Cancer Radiation Therapy Unknown Date (has links) Stereotactic Body Radiation Therapy (SBRT) is a modern precision radiation therapy to deliver the dose in 1 to 5 fractions with high target dose conformity, and steep dose gradient towards healthy tissues. The dose delivered is influenced by the leaf width of the MLC, especially in case of SBRT. Treatment plans with high definition (HD) MLC having leaf-width 2.5 mm and normal MLC having leaf-width 5 mm, were compared to quantify dosimetric and radiobiological parameters. Dosimetric parameters conformity indices (CI), gradient indices (GI) and heterogeneity indices (HI) were compared. The radiobiological parameters were evaluated by normal tissue complication probability (NTCP) and tumor control probability (TCP) based on the equivalent uniform dose (EUD). The results show that there is dosimetric and radiobiological merit of the HD MLC over the normal MLC. However, the improvement is not consistent with all the plans and thus further research is required prior to conclusion. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2018. / FAU Electronic Theses and Dissertations Collection Radiosurgery Lung Neoplasms Radiation dosimetry Radiobiology
106	Towards a European Space Radiation Risk Model: : Knowledge gaps and risk model concept Nilsson, Sandra January 2019 (has links) Space travelling within the solar system is expected to expand within the upcoming years, with the Moon and Mars as main targets. These longer space flights results in longer time periods within a complex radiation environment for the astronauts. Dose limits therefore have to be established by space agencies for their respective space workers, to secure maximum safety and as low risks as possible. A radiation model is constructed by many building blocks, ranging from radiobiology to physics. The state of the art of the current models are described in this paper, followed by the uncertainties and knowledge gaps related to the respective space agency’s approach. These mainly include more extensive research of the available data for exposed populations, adapting the inputs to the relevant population, and the choice of risk quantity and track structure models. By focusing on the largest uncertainty contributors, Europe can add importance to this essential research and form a European space radiation model for European space workers. Radiobiology Space Radiation Aerospace Engineering Rymd- och flygteknik
107	Synchrotron microbeam radiation therapy Crosbie, Jeffrey January 2008 (has links) This thesis presents interdisciplinary, collaborative research in the field of synchrotron microbeam radiation therapy (MRT). Synchrotron MRT is an experimental radiotherapy technique under consideration for clinical use, following demonstration of efficacy in tumour-bearing rodent models with remarkable sparing of normal tissue. A high flux, X-ray beam from a synchrotron is segmented into micro-planar arrays of narrow beams, typically 25 μm wide and with peak-to-peak separations of 200 μm. The radiobiological effect of MRT and the underlying cellular mechanisms are poorly understood. The ratio between dose in the ‘peaks’of the microbeams to the dose in the ‘valleys’, between the microbeams, has strong biological significance. However, there are difficulties in accurately measuring the dose distribution for MRT. The aim of this thesis is to address elements of both the dosimetric and radiobiological gaps that exist in the field of synchrotron MRT. A method of film dosimetry and microdensitometry was adapted in order to measure the peak-to-valley dose ratios for synchrotron MRT. Two types of radiochromic film were irradiated in a phantom and also flush against a microbeam collimator on beamline BL28B2 at the SPring-8 synchrotron. The HD-810 and EBT varieties of radiochromic film were used to record peak dose and valley dose respectively. In other experiments, a dose build-up effect was investigated and the half value layer of the beam with and without the microbeam collimator was measured to investigate the effect of the collimator on the beam quality. The valley dose obtained for films placed flush against the collimator was approximately 0.25% of the peak dose. Within the water phantom, the valley dose had increased to between 0.7–1.8% of the peak dose, depending on the depth in the phantom. We also demonstrated, experimentally and by Monte Carlo simulation, that the dose is not maximal on the surface and that there is a dose build-up effect. The microbeam collimator did not make an appreciable difference to the beam quality. The measured values of peak-to-valley dose ratio were higher than those predicted by previously published Monte Carlo simulation papers. For the radiobiological studies, planar (560 Gy) or cross-planar (2 x 280 Gy or 2 x 560 Gy) irradiations were delivered to mice inoculated with mammary tumours in their leg, on beamline BL28B2 at the SPring-8 synchrotron. Immunohistochemical staining for DNA double strand breaks, proliferation and apoptosis was performed on irradiated tissue sections. The MRT response was compared to conventional radiotherapy at 11, 22 or 44 Gy. The results of the study provides the first evidence for a differential tissue response at a cellular level between normal and tumour tissues following synchrotron MRT. Within 24 hours of MRT to tumour, obvious cell migration had occurred into and out of irradiated zones. MRT-irradiated tumours showed significantly less proliferative capacity by 24 hours post-irradiation (P = 0.002). Median survival times for EMT-6.5 and 67NR tumour-bearing mice following MRT (2 x 560 Gy) and conventional radiotherapy (22 Gy) increased significantly compared to unirradiated controls (P < 0.0005). However, there was markedly less normal tissue damage from MRT than from conventional radiotherapy. MRT-treated normal skin mounts a more coordinated repair response than tumours. Cell-cell communication of death signals from directly irradiated, migrating cells, may explain why tumours are less resistant to high dose MRT than normal tissue. Microbeam radiation therapy Cancer Dosimetry Synchrotron Radiobiology
108	Influence de la distribution de dose d’irradiation dans la variation de l’effet radiobiologique du traitement radiochirurgical par Gamma Knife / Influence of radiation dose distribution in radiobiological modifications after Gamma Knife radiosurgery Massager, Nicolas 18 February 2008 (has links) La radiochirurgie par Gamma Knife constitue une modalité thérapeutique reconnue de certaines affections cérébrales. Le traitement se base sur l’administration d’un rayonnement focalisé au niveau d’une cible intracrânienne. L’efficacité de ce traitement repose sur la délivrance d’une dose d’irradiation efficace au sein d’un volume-cible associé à la délivrance d’une dose d’irradiation négligeable à l’extérieur de ce même volume-cible. En pratique, la dose d’irradiation administrée à l’intérieur du volume-cible n’est pas distribuée de manière homogène, et la dose d’irradiation reçue par les tissus situés en-dehors du volume-cible n’est pas nécessairement faible. Notre travail est basé sur l’hypothèse que l’imperfection de la distribution de la dose d’irradiation au sein du volume-cible et en-dehors de celui-ci peut être responsable des échecs et des complications rencontrées en radiochirurgie. Dans deux modèles cliniques de traitement radiochirurgical, le schwannome vestibulaire et la névralgie du trijumeau, nous avons montré qu’il existait une relation entre les paramètres de distribution de dose d’irradiation et certains résultats du traitement radiochirurgical par Gamma Knife de ces pathologies. Nous avons développé deux modèles expérimentaux d’irradiation radiochirurgicale de rats, l’un ciblé sur le striatum et l’autre sur le nerf trijumeau, permettant d’analyser les conséquences histologiques des variations de la distribution de dose à l’intérieur du volume-cible ainsi qu’à distance de celui-ci. Nous avons démontré que la réponse radiobiologique des tissus irradiés était fortement dépendante de ce paramètre dosimétrique, et que ce dernier constituait une donnée de la planification chirurgicale aussi importante que la dose de prescription. Nous avons corrélé ces résultats avec certaines observations réalisées dans d’autres indications de traitement radiochirurgical ainsi que dans l’analyse histologique de tumeurs traitées par Gamma Knife. Ces études mettent en évidence le rôle important joué par l’optimalisation de la distribution de la dose d’irradiation dans l’amélioration des résultats cliniques du traitement radiochirurgical. Les valeurs optimales de la distribution de dose dans les différentes indications de traitement radiochirurgical doivent être recherchées, et les différentes méthodes mises à notre disposition lors de la planification dosimétrique pour améliorer la distribution de dose doivent être utilisées avec discernement pour obtenir la dosimétrie radiochirurgicale la plus parfaite possible. Gamma Knife radiosurgery radiobiology histology dose distribution
109	Improving the therapeutic ratio of stereotactic radiosurgery and radiotherapy Andisheh, Bahram January 2012 (has links) New methods of high dose delivery, such as intensity modulated radiation therapy (IMRT), stereotactic radiation therapy (SRT) or stereotactic radiosurgery (SRS), hadron therapy, tomotherapy, etc., all make use of a few large fractions. To improve these treatments, there are three main directions: (i) improving physical dose distribution, (ii) optimizing radiosurgery dose-time scheme and (iii) modifying dose response of tumors or normal tissues. Different radiation modalities and systems have been developed to deliver the best possible physical dose to the target while keeping radiation to normal tissue minimum. Although applications of radiobiological findings to clinical practice are still at an early stage, many studies have shown that sublethal radiation damage repair kinetics plays an important role in tissue response to radiation. The purpose of the present thesis is to show how the above-mentioned directions could be used to improve treatment outcomes with special interest in radiation modalities and dose-time scheme, as well as radiobiological modeling. Also for arteriovenous malformations (AVM), the possible impact of AVM network angiostructure in radiation response was studied. / Nya och förbättrade metoder för precisionsbestrålning, såsom intensitetsmodulerad strålbehandling (IMRT), stereotaktisk strålbehandling (SRT), stereotaktisk strålkirurgi (SRS) eller hadronterapi etc., gör det möjligt att leverera behandlingen i ett fåtal fraktioner med höga doser. Dessa behandlingmetoder kan ytterligare förbättras genom att (i) förbättra den fysikaliska dosfördelningen, (ii) optimera dosrater och fraktioneringsscheman eller (iii) modifiera dosresponsen hos tumörer eller normalvävnad. Olika strålmodaliteter och behandlingssystem har tagits fram för att kunna leverera bästa möjliga fysikaliska dosfördelning till targetvolymen samtidigt som dosen till frisk vävnad hålls så låg som möjligt. Även om användandet av radiobiologisk kunskap och modeller i klinisk rutin ännu är i sin linda så visar många studier att kinetiken för subletal reparation av strålskador har stor betydelse för strålresponsen. Syftet med denna avhandling är att visa hur dessa olika utvecklingsvägar kan användas för att förbättra behandlingsresultatet speciellt genom att studera vald strålmodalitet, dosrat och fraktioneringsschema samt radiobiologisk modellering. För arteriovenösa missbildningar (AVM) har även studerats hur strukturen hos angionätverket påverkar strålresponsen. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p> optimization stereotactic radiosurgery stereotactic radiotherapy radiobiology modeling
110	Non-targeted effects of ionizing radiation in vivo : epigenetic aspects / Yaroslav Ilinytskyy Ilnytskyy, Yaroslav, University of Lethbridge. Faculty of Arts and Science January 2010 (has links) The classical paradigm of radiation biology is based on the notion that ionizing particle has to traverse a nucleus of a living cell in order to damage genetic material either directly or via production of short living free radicals. After DNA damage is introduced it can be either safely repaired and the cell can continue divisions unaltered; or it can result in a failure to repair and cells death; or finally, upon misrepair, the cell would be carrying genetic alteration that could result in cancer or developmental abnormality. Therefore modern risk estimations are based on the notion that nucleus is the true target of radiation effects and those are essentially stochastic with linear dependence on the dose. During the last two decades or so, a different idea was developed based on the observation that irradiated cells can communicate radiation induced stress signals to their unaffected neighbors and themselves become reprogrammed to maintained abnormal radiation-induced phenotype across multiple cellular divisions. Even more astonishingly this phenotype maybe transmitted by irradiated germ cells to unexposed progeny. Here we suggest that these non-targeted effects are maintained by epigenetic mechanisms and examine epigenetic underpinnings of bystander and transgenerational effects in vivo. / xi, 190 leaves ; 28 cm Radiobiology Radiation -- Physiological effect Dissertations, Academic

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