Aardaneh, K., & van der Walt, T. (2006). Ga2O for target, solvent extraction for radiochemical separation and SnO2for the preparation of a68Ge/68Ga generator. ,Journal of Radioanalytical and Nuclear Chemistry. 268 (1), 25-32.
Ambe, S. (1987). 68Ge/68Ga, generator with alpha-ferric oxide support. Applied Radiation and Isotopes. 39, 49-51.
Asti, M., De Pietri, G., Fraternali, A., Grassi, E., Sghedonİ, R., Fioroni, F., . . . Salvo, D. (2008).
Validation of (68)Ge/(68)Ga generator processing by chemical purification for routine clinical application of (68)Ga-DOTATOC. Nuclear Medicine and Biology. 35, 721-724.
Attila, Ö., King, H. E., Meirer, F., & Weckhuysen, B. M. (2019). 3D Raman Spectroscopy of Large Zeolite ZSM-5 Crystals. Chemistry – A European Journal. 25, 7158-7167.
Bao, B., & Song, M. (1996). A new 68Ge/68Ga generator based on CeO2. Journal of Radioanalytical and Nuclear Chemistry. 213, 233–238.
Bhardwaj, N., & Mohapatra, S. (2015). Fabrication of SnO2 three dimentional complex microcrystal chains by carbothermal reduction method. Advanced Materials Letters. 6 (2), 148-152.
Buwa, S. (2014). Production and Evaluation of a TiO2 based 68Ge/68Ga Generator. Doctoral Dissertation, University of the Western Cape.
Cao, B., Li, Z., & Wang, Y. (1998). 68Ge/68Ga generator with alpha-ferric oxide support in trigonal structure. Journal of Radioanalytical and Nuclear Chemistry. 238 (1-2), 175-178.
Chakravarty , R. (2011). Development Of Radionuclide Generators For Biomedical Applications.
Doctoral Dissertation, Homi Bhabha National Institute.
Chakravarty, R., Chakraborty, S., Shukla, R., Bahadur, J., Ram, R., Mazumder, S., . . . Dash, A.
(2016). Mechanochemical Synthesis of Mesoporous Tin Oxide: A New Generation Nanosorbent for 68Ge/68Ga Generator Technology. Dalton Transaction, 45 13361-13372.
Chakravarty, R., Shukla, R., Ram, R., Tyagi, A. K., Dash,, A., & Venkatesh, M. (2011). Development of a nano-zirconia based 68Ge/68Ga generator for biomedical applications. Nuclear Medicine and Biology. 38 (4), 575-583.
Chakravarty, R., Shukla, R., Ram, R., Venkatesh, M., Dash, A., & Tyagi, A. K. (2010). Nanoceria-PAN Composite-Based Advanced Sorbent Material: A Major Step Forward in the Field of Clinical-Grade 68Ge/68Ga Generator. Radiopharmaceuticals Division. 2 (7), 2069-2075.
Challagulla, S., Tarafder, K., Ganesan, R., & Roy, S. (2017). Structure sensitive photocatalytic reduction of nitroarenes over TiO2. Scientific Reports. 7 .
Cheng, W.-L., Jao, Y., Lee, C.-S., & Lo , A.-R. (2000). Preparation of 68Ge/68Ga Generator with a Binary Ga/Ag Electrodepositions as Solid Target. Journal of Radioanalytical and Nuclear Chemistry. 245 (1), 25-30.
60
Çetin, C. E. (2011). Mikrodalga ışınlanması ile çeşitli metal-kükürt yarı iletken nanoparçacıklarının sentezi ve karakterizasyonu. Yüksek Lisans Tezi, Ankara Üniversitesi.
Dash, A., & Chakravarty, R. (2017). Nanomaterial-Based Adsorbent:Promises, Opportunities, and Challenges to Develop Column Chromatography Radionuclide Generators for Nuclear Medicine. Separation & Purification Reviews. 46 (2), 91-107.
Davids, C. R. (2017). Monitoring various eluate characteristics of the iThemba LABS. Doctoral Dissertation, Stellenbosch University.
Davies, C. M. (2012). Determination Of Distribution Coefficients For Cation Exchange Resin And Optimisation Of Ion Exchange Chromatography For Chromıum Separation For Geological Materials. Doctoral Dissertation. The University of Manchester.
de Blois, E., Chan, H., Naidoo, C., Prince, D., Krenning, E. P., & Breeman, W. A. (2011).
Characteristics of SnO2-based 68Ge/68Ga generator and aspects of radiolabelling DOTA-peptides. Applied Radiation and Isotopes. 69 (2), 308-315.
Demirdioğlu, B.. (2009). Gama Spektrometrisine Giriş. Türkiye Atom Enerjisi Kurumu.
Egamediev, S. K., Khujaev, S., & Mamatkazina , A. K. (2000). Influence of Preliminary Treatment of Aluminum Oxide on the Separation of 68Ge-68Ga Radionuclide Chain. Journal of Radioanalytical and Nuclear Chemistry. 246 (3), 593–596.
el-sherbiny, S., Morsy, F. A., Samir, M., & Fouad, O. A. (2014). Synthesis, characterization and application of TiO2 nanopowders as special paper coating pigment. Applied Nanoscience, 305-303.
Fazaeli, Y., Jalilian, A. R., Amini, M. M., Ardaneh, K., Rahiminejad, A., Bolourinovin, F., . . . Majdabadi, A. (2012). Development of a (68)Ga-Fluorinated Porphyrin Complex as a Possible PET Imaging Agent. Nuclear Medicine and Molecular Imaging. 46 (1), 20-26.
Girardi, F., Pietra, R., & Sabbioni, E. (1970). Radiochemical separations by retention on ionic precipitate adsorption tests on 11 materials. Journal of Radioanalytical Chemistry. 5, 141-171.
Gleason, G. I. (1960). A Positron Cow. International Journal of Applied Radiation and Isotopes. 8, 90-94.
Greene, M. W., & Tucker, W. (1961). An improved Gallium-68 cow. The International Journal of Applied Radiation and Isotopes. 12 (62).
Han, D. H., Shin, S.-H., & Petrov, S. (2004). Crosslinking and degradation of polypropylene by electron beam irradiation in the presence of trifunctional monomers. Radiation Physics and Chemistry. 69(3), 239-244.
Hodgson, P. E., Gadioli, E., & Gadioli Erba, E. (1997). Introductory Nuclear Physics. Oxford:
Clarendon Press.
IAEA. (2003). Manual for Reactor Produced Radioisotopes, TECDOC-1340. Vienna: International Atomic Energy Agency.
61
IAEA. (2005). Report of Consultants Meeting on Radionuclide Generators for Industrial Radiotracer Technology. Vienna: Radionuclide generators. Handbook of Nuclear Chemistry.
IAEA. (2009). Cyclotron Produced Radionuclides: Physical Characteristics and Production Methods, TECDOC-468. Vienna: International Atomic Energy Agency.
IAEA. (2010). Production Of Long Lived Parent Radionuclides For Generators: 68Ge, 82Sr, 90Sr And 188W. Vienna: International Atomic Energy Agency.
IAEA. (2013). Radiotracer generators for industrial applications (Radiation Technology Series No:5). Vienna: International Atomic Energy Agency.
IAEA. (2019). Gallium-68 Cyclotron Production. Vienna: International Atomic Energy Agency.
IAEA. (2021). Alternative Radionuclide Production with a Cyclotron. Vienna: International Atomic Energy Agency.
Karthik, T. V., Maldonado, A., & Olvera, M. d. (2012). Synthesis of tin oxide powders by homogeneous precipitation. Structural and morphological characterization. 9th International Conference on Electrical Engineering.
Kopecký, P., & Mudrová, B. (1974). 68Ge68Ga generator for the production of 68Ga in an ionic form. The International Journal of Applied Radiation and Isotopes. 25, 263–268.
Kopecký, P., Mudrová, B., & Svoboda, K. (1973). The study of conditions for the preparation and utilization of 68Ge68Ga generator. The International Journal of Applied Radiation and Isotopes. 24, 73-80.
L'Annunziata, M. F. (2007). Radioactivity: Introduction and History. The Netherlands: Elsevier.
Loc’h, C., Maziére, B., & Comar, D. (1980). A new generator for ionic gallium-68. . Journal of Nuclear Medicine. 21, 171-173.
Malley, M. C. (2011). Radioactivity: A History of a Mysterious Science. Oxford: Oxford University Press.
Malyshev, K. V., & Smirnov, V. V. (1975). Gallium-68 yield from hydrated zirconium oxide based generator. Sov. Radiochim. 17, 137-140.
McElvany, K., Hopkins, K., & Welch, M. (1984). Comparison of 68Ge/68Ga generator systems for radiopharmaceutical production. The International Journal of Applied Radiation and Isotopes. 35 (6), 521-524.
Meinkin, G. E., Kurczak, S., Mausner, L. F., Kolsky, K. L., & Srivastava, S. C. (2005). Production of high specific activity 68Ge at Brookhaven National Laboratory. Journal of Radioanalytical and Nuclear Chemistry 263, 553-557.
Meyer, G. J., Macke, H., Schuhmacher, J., & Knapp, W. (2004). 68Ga-labelled DOTA-derivatised peptide ligands. European Journal of Nuclear Medicine and Molecular Imaging. 31, 1097-1104.
62
Mya, O. B., Bita, M., Louafi, I., & Djouadi, A. (2018). Esterification process catalyzed by ZSM-5 zeolitesynthesized via modified hydrothermal method. MethodsX. 5, 277-282.
Naidoo, C., van der Walt, T. N., & Raubenheime, H. G. (2002). Cyclotron production of 68Ge with a Ga2O target. Journal of Radioanalytical and Nuclear Chemistry. 253(2), 221-225.
Nakayama, M., Haratake, M., Ono, M., Harada, K., Nakayama, H., Yahara, S., . . . Arano, Y. (2003).
A new 68Ge/68Ga generator system using an organic polymer containing N-methylglucamine groups as adsorbent for 68Ge. Applied Radiation and Isotopes. 58 (1), 9-14.
Neirinckx, R. D., Layne, W. W., Sawan, S. P., & Davis, M. A. (1982). Development of an ionic germanium 68 gallium 68 generator III.chelate resins as chromatographic substrates for germanium. International Journal of Applied Radiation and Isotopes. 33 (4), 259-266.
Ocak, M., Antretter, M., Knopp, R., Kunkel, F., Petrik, M., Bergisadi, N., & Decristoforo, C. (2010).
Full automation of (68)Ga labelling of DOTA-peptides including cation exchange prepurification. Applied Radiation and Isotopes. 68, 297-302.
Petrik, M., Knetsch, P., Knopp, R., Imperato, G., Ocak, M., von Guggenberg, E., . . . Silbernagl, R.
(2011). Radiolabelling of peptides for PET, SPECT and therapeutic applications using a fully automated disposable cassette system. Nuclear Medicine Communications. 32, 887-895.
Pijarowska-Kruszyna, J., Pociegiel, M., & Mikolajczak, R. (2021). Reference Module in Biomedical Sciences. Radionuclide generators. Elsevier.
Qaim, S. M. (2010). Radiochemical determination of nuclear data for theory and applications.
Journal of Radioanalytical and Nuclear Chemistry. 284, 489-505.
Razbash, A. A. (2003). A simple gallium-68 generator. European Journal of Nuclear Medicine and Molecular Imaging. 30 (2), S318.
Richards, P. (1960). A survey of the production at Brookhaven National Laboratory of radioisotopes for medical research. Transactions American Nuclear Society.; VII Rassegna Internazionale Elettronica e Nucleare, 223-224.
Romero, E., & Morcillo, M. A. (2017). Inorganic oxides with potential application in the preparation of a 68Ge/68Ga generator system. Applied Radiation and Isotopes. 119, 28-35.
Romero, E., Martínez, A., Oteo, M., Ibañez, M., Santos, M., & Morcillo, M. Á. (2020). Development and long-term evaluation of a new 68Ge/68Ga generator based on nano-SnO2 for PET imaging. Scientific Reports. 10.
Rösch, F. (2012). Past, present and futureof 68Ge/68Ga generators. Applied Radiation and Isotopes.
76, 24-30.
Rösch, F. (2013). 68Ga radiopharmaceuticals: Current status and future. Germany: Johannes Gutenberg University.
Rösch, F., & Knapp, R. F. (2003). Radionuclide generators. Handbook of Nuclear Chemistry.
63
Rzaij, J. M., & Abass, A. M. (2020). Review on: TiO2 Thin Film as a Metal Oxide Gas Sensor.
Journal of Chemical Reviews. 2, 114-121.
Saha, G. B. (2010). Fundamentals of Nuclear Pharmacy. New York: Springer.
Schaffer, P., Bénard, F., Bernstein, A., Buckley, K., Celler, C., Cockburn, N., . . . Zavodszky, P. A.
(2015). Direct Production Of 99mTc via 100Mo(p,2n) on Small Medical Cyclotrons. Physics Procedia. 66, 383-395.
Schuhmacher, J., & Maier-Borst, W. (1981). A new 68Ge/68Ga radioisotope generator system for production of 68Ga in dilute HCl. The International Journal of Applied Radiation and Isotopes. 32, 31-36.
Tang, Q., Zhao, G., Luo, W., & LI, D. (1997). Preparation and study of a 68Ge/68Ga Generator.
Journal of Nuclear and Radiochemical Sciences. 19 (2), 29-33.
Thomas, R. (2004). Practical Guide to ICP-MS. Newyork: Marcel Dekker, Inc.
Tucker, W. D., Greene, M. W., Weiss, A. J., & Murrenhoff, A. (1958). Methods of preparation of some carrier-free radioisotopes involving sorption on alümina. Brookhaven National Lab., Upton, N.Y.
Velikyan, I. (2015). 68Ga-Based Radiopharmaceuticals: Production and Application Relationship.
Molecules. 20,, 12913-12943.
Vértes, A., Nagy, S., & Klencsár, Z. (2011). Handbook of Nuclear Chemistry. New York: Springer.
Yan, X., Li, Y., & Xia, T. (2017). Black Titanium Dioxide Nanomaterials in Photocatalysis.
International Journal of Photoenergy.
Yano, Y., & Anger, H. O. (1964). A Gallium Positron Cow for Medical Use. Journal of Nuclear Medicine. 5, 485-488.
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ETİK KURALLARA UYGUNLUK BEYANI
Uzmanlık tezi olarak sunduğum bu çalışmayı, bilimsel ahlak ve geleneklere aykırı düşecek bir yol ve yardıma başvurmaksızın yazdığımı, yararlandığım eserlerin kaynak listesinde gösterilenlerden oluştuğunu, bunlardan her seferinde değinme yaparak yararlandığımı ve Atom Enerjisi Uzmanlığı Yönetmeliğine ve Atom Enerjisi Uzmanlığı Tez Hazırlama Yönergesine uygun olarak hazırladığımı belirtir ve bunu doğrularım. Türkiye Enerji, Nükleer ve Maden Araştırma Kurumu tarafından belli bir zamana bağlı olmaksızın, tezimle ilgili yaptığım bu beyana aykırı bir durumun saptanması durumunda, ortaya çıkacak tüm ahlaki ve hukuki sonuçlara katlanacağımı bildiririm.
18/08/2022 Elif EKEBAŞ ÇAVDAR