This research studied Ho166/PLLA microspheres, a promising treatment for tumours in the liver. The Ho166 is generated through a neutron capture reaction during irradiation in a nuclear reactor. Previous work has found that neutron-irradiation in-core causes damage to microspheres and causes additional degradation to progress once suspended in media. The cause of this damage was not well understood and is the focus of this research. This research studied factors present in-core such as heat, gamma radiation, and impacts of lead shielding, for their impact on microsphere quality. Additionally, this research looked at the potential of reactive oxygen species causing damage once microspheres are suspended in liquid.
Thresholds for damage were identified to correlate with the glass transition temperature of poly- l-lactic acid. Exposure to gamma radiation induces heating, as well as structural changes to the polymer which shifts the temperature where the glass transition occurs. Damage formed from gamma radiation, independent of other variables, was seen at extreme accumulated doses. Notably, exposure to gamma radiation and heat did not cause a progression of damage over time. Samples exposed only to these factors remained stable in solution for extended periods. A theory was proposed that reactive oxygen species formed by the interaction of ionizing radiation with the suspending media may be causing the progression of damage over time. This factor would only be present for microspheres having undergone neutron capture reactions, forming radioactive holmium. Testing confirmed a potential impact of radiation interactions with the suspending media contributing to damage progression. Several thicknesses of lead shielding surrounding the sample chamber were tested in-core. There were significant impacts on temperature, neutron flux, and microsphere quality. / Thesis / Master of Science (MSc) / This research studied Ho166/PLLA microspheres, a promising treatment for tumours in the liver. The preparation of this treatment includes microspheres being neutron irradiated in the core of a nuclear reactor. Irradiation in-core leads to damage of microspheres. This research studied factors present in-core such as heat, gamma radiation, and thickness of lead shielding, for their impact on microsphere quality. Additionally, this research looked at the potential of reactive oxygen species causing damage once microspheres are suspended in liquid. Thresholds for damage were identified for temperature and gamma radiation exposure. Radiation interactions in liquid suggest possible damaging effects over time. Finally changing the thickness of lead shielding in core had significant impact on temperature, neutron flux, and microsphere quality.
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/29020 |
Date | January 2023 |
Creators | Tigwell, Mackenzie |
Contributors | Armstrong, Andrea, Physics |
Source Sets | McMaster University |
Language | English |
Detected Language | English |
Type | Thesis |
Page generated in 0.0028 seconds