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Atomic layer deposition (ALD) is a versatile gas phase coating technique that allows coating of complex structured materials, as well as high-surface area materials such as nanoparticles. In this work, ALD is used to deposit a lutetium oxide layer on TiO2 nanoparticles (P25) in a fluidized bed reactor to produce particles for nuclear medical applications. Two precursors were tested: the commercially available Lu(TMHD)3 and the custom-made Lu(HMDS)3. Using Lu(TMHD)3, a lutetium loading up to 15 wt. % could be obtained, while using Lu(HMDS)3, only 0.16 wt. % Lu could be deposited due to decomposition of the precursor. Furthermore, it was observed that vibration-assisted fluidization allows for better fluidization of the nanoparticles and hence a higher degree of coating.
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Atomic layer deposition (ALD) is a versatile gas phase coating technique that allows coating of complex structured materials, as well as high-surface area materials such as nanoparticles. In this work, ALD is used to deposit a lutetium oxide layer on TiO2 nanoparticles (P25) in a fluidized bed reactor to produce particles for nuclear medical applications. Two precursors were tested: the commercially available Lu(TMHD)3 and the custom-made Lu(HMDS)3. Using Lu(TMHD)3, a lutetium loading up to 15 wt. % could be obtained, while using Lu(HMDS)3, only 0.16 wt. % Lu could be deposited due to decomposition of the precursor. Furthermore, it was observed that vibration-assisted fluidization allows for better fluidization of the nanoparticles and hence a higher degree of coating.
Cu is an important trace metal which plays a role in many biological processes. The radioisotope 64Cu is often used to study such processes. Furthermore, 64Cu finds applications in cancer diagnostics as well as therapy. For all of these applications 64Cu having high specific activity is needed. 64Cu can be produced in cyclotrons or in nuclear reactors. In this paper we study the effect of gamma dose on the production of 64Cu according to the Szilard-Chalmers reaction using Cu(II)-phthalocyanine as a target. For this purpose, irradiations were performed in the nuclear reactor of the Delft University of Technology using a novel irradiation facility helping to limit the dose produced by gammas present in the reactor pool. The obtained 64Cu activity yield was in general above 60% in accordance to the theoretical expected value. An increase in gamma dose has no significant influence on the obtained activity yield but increases the loss of Cu from Cu(II)-phthalocyanine up to 0.9% and hence decreases the specific activity that can be obtained. However, without optimisation, when reducing the gamma dose specific activities in the order of 30 TBq/g can be achieved.
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Cu is an important trace metal which plays a role in many biological processes. The radioisotope 64Cu is often used to study such processes. Furthermore, 64Cu finds applications in cancer diagnostics as well as therapy. For all of these applications 64Cu having high specific activity is needed. 64Cu can be produced in cyclotrons or in nuclear reactors. In this paper we study the effect of gamma dose on the production of 64Cu according to the Szilard-Chalmers reaction using Cu(II)-phthalocyanine as a target. For this purpose, irradiations were performed in the nuclear reactor of the Delft University of Technology using a novel irradiation facility helping to limit the dose produced by gammas present in the reactor pool. The obtained 64Cu activity yield was in general above 60% in accordance to the theoretical expected value. An increase in gamma dose has no significant influence on the obtained activity yield but increases the loss of Cu from Cu(II)-phthalocyanine up to 0.9% and hence decreases the specific activity that can be obtained. However, without optimisation, when reducing the gamma dose specific activities in the order of 30 TBq/g can be achieved.
Radionuclides are often used in the field of nuclear medicine. For some deceases the use of radionuclides is the best possible care, or even the only means of diagnosis or treatment. For these medical applications high specific activity (high activity per unit of mass) is required. Commonly, medical radionuclides are man-made. They can either be produced by neutron activation, charged particle or photon activation or by means of radionuclide generator. Furthermore, hospitals prefer an ‘on demand’ supply. A radionuclide generator is ideal. Radionuclide generators can also be used to produce high specific activity. Conventional radionuclide generators work with the principle that the mother and daughter radionuclide have different electrostatic interactions with the column material. This allows for easy elution of the daughter radionuclide. However, when working with chemical identical mother-daughter radionuclide pairs (e.g. 177mLu / 177Lu) another separation principle is required. Utilising ‘hot atom’ chemical principles such a mother-daughter pairs can be separated. ‘Hot atom’ principles describe the chemical effects that occur due to nuclear interactions or due to decay. An example of these effects is bond rupture. The effective range of those principles is rather limited, requiring thin layers. A possible technique to apply these thin layers is atomic layer deposition (ALD). ALD is commonly used in the semi-conductor industry, but can due to its versatility also be used in the field of catalysis or pharmaceutical. The advantage of using ALD is that this gas phase deposition technique allows for thin conformal coating of complex structured materials. Furthermore, the amount of material that can be deposited can easily be adapted to need because ALD is a self-limiting process. In this thesis the usefulness of ALD in combination with radionuclide production is explored. Because of the versatility of ALD it can also be used to create target materials for charged particle activation and enrichment experiments (Chapter 2). This versatility is illustrated by three case studies, namely this production of targets for 64Cu production, the production of 177Lu by means of a radionuclide generator and the production of 99Mo using three different routes. Also described is how ALD can be used to alter the surface chemistry of high surface area materials to increase their adsorption capacity for Mo (Chapter 3). The obtained particles with an alumina coating are then tested for their adsorption capacity and compared to acid activated alumina, the current used material in 99Mo/99mTc-radionuclide generators. The adsorption capacity of the obtained particles is twice that of acid activated alumina and has a 99mTc elution efficiency of 55%. Furthermore, the coating of nano-particles for the development of with Lu coated particles (Chapter 4) for the preparation of a radionuclide generator is described. ALD allows for a deposition of up to 15w% Lu. Furthermore, the gamma dose received during neutron activation has an influence on the specific activity produced (Chapter 5). Using Cu(II)-phthalocyanine as a target it is shown that an increase in gamma dose during neutron activation results in an increase in Cu release and hence a decrease in specific activity obtained. ...
Radionuclides are often used in the field of nuclear medicine. For some deceases the use of radionuclides is the best possible care, or even the only means of diagnosis or treatment. For these medical applications high specific activity (high activity per unit of mass) is required. Commonly, medical radionuclides are man-made. They can either be produced by neutron activation, charged particle or photon activation or by means of radionuclide generator. Furthermore, hospitals prefer an ‘on demand’ supply. A radionuclide generator is ideal. Radionuclide generators can also be used to produce high specific activity. Conventional radionuclide generators work with the principle that the mother and daughter radionuclide have different electrostatic interactions with the column material. This allows for easy elution of the daughter radionuclide. However, when working with chemical identical mother-daughter radionuclide pairs (e.g. 177mLu / 177Lu) another separation principle is required. Utilising ‘hot atom’ chemical principles such a mother-daughter pairs can be separated. ‘Hot atom’ principles describe the chemical effects that occur due to nuclear interactions or due to decay. An example of these effects is bond rupture. The effective range of those principles is rather limited, requiring thin layers. A possible technique to apply these thin layers is atomic layer deposition (ALD). ALD is commonly used in the semi-conductor industry, but can due to its versatility also be used in the field of catalysis or pharmaceutical. The advantage of using ALD is that this gas phase deposition technique allows for thin conformal coating of complex structured materials. Furthermore, the amount of material that can be deposited can easily be adapted to need because ALD is a self-limiting process. In this thesis the usefulness of ALD in combination with radionuclide production is explored. Because of the versatility of ALD it can also be used to create target materials for charged particle activation and enrichment experiments (Chapter 2). This versatility is illustrated by three case studies, namely this production of targets for 64Cu production, the production of 177Lu by means of a radionuclide generator and the production of 99Mo using three different routes. Also described is how ALD can be used to alter the surface chemistry of high surface area materials to increase their adsorption capacity for Mo (Chapter 3). The obtained particles with an alumina coating are then tested for their adsorption capacity and compared to acid activated alumina, the current used material in 99Mo/99mTc-radionuclide generators. The adsorption capacity of the obtained particles is twice that of acid activated alumina and has a 99mTc elution efficiency of 55%. Furthermore, the coating of nano-particles for the development of with Lu coated particles (Chapter 4) for the preparation of a radionuclide generator is described. ALD allows for a deposition of up to 15w% Lu. Furthermore, the gamma dose received during neutron activation has an influence on the specific activity produced (Chapter 5). Using Cu(II)-phthalocyanine as a target it is shown that an increase in gamma dose during neutron activation results in an increase in Cu release and hence a decrease in specific activity obtained.