Falco Reissig1, Gerd Wunderlich2, Roswitha Runge2, Robert Freudenberg2, Armin Lühr3, Jörg Kotzerke4. 1. University Hospital, Faculty of Medicine Carl Gustav Carus, Technische Universität Dresden, Department of Nuclear Medicine, Dresden, Germany; Helmholtz-Zentrum Dresden-Rossendorf, Institute of Radiopharmaceutical Cancer Research, Dresden, Germany. 2. University Hospital, Faculty of Medicine Carl Gustav Carus, Technische Universität Dresden, Department of Nuclear Medicine, Dresden, Germany. 3. OncoRay - National Center for Radiation Research in Oncology, Faculty of Medicine, University Hospital Carl Gustav Carus, Technische Universität Dresden, Helmholtz-Zentrum Dresden - Rossendorf, Dresden, Germany. 4. University Hospital, Faculty of Medicine Carl Gustav Carus, Technische Universität Dresden, Department of Nuclear Medicine, Dresden, Germany. Electronic address: joerg.kotzerke@mailbox.tu-dresden.de.
Abstract
INTRODUCTION: Radiation-induced DNA damage occurs from direct and indirect effects. The induction is influenced by the physical characteristics of the radionuclide, especially its linear energy transfer. Hypoxia reduces the effect of irradiation treatment in tumor cells and leads to poor patient outcomes. High linear energy transfer emitters can overcome this obstacle. Our aim is to demonstrate the influence of hypoxia on the interaction of different radiation qualities with isolated DNA. METHODS: PuC19 Plasmid DNA was irradiated with 223Ra, 188Re, 99mTc and 99mTc-labeled pyrene with and without DMSO under hypoxia or normoxic conditions. DNA damages in form of single-(SSB) and double-strand breaks (DSB) were analyzed by gel electrophoresis. RESULTS: Radiation doses up to 200 Gy of 223Ra, 188Re and 99mTc led to maximal yields of 80% SSB and 30%, 28% and 32% DSB, respectively. Hypoxia had minor effects on damages from 223Ra, but caused a small enhancement in DSB for 188Re and 99mTc. DMSO prevented DSB completely and reduced SSB from the "free" radionuclides to comparable levels. DNA-binding 99mTc-labeled pyrene induced less SSB and DSB compared to [99mTc]TcO4-. However, the incubation with DMSO could prevent the SSB and DSB induction only to a minor extent. CONCLUSIONS: Hypoxia does not limit DNA damage induced by 223Ra, 188Re, 99mTc and 99mTc-labeled pyrene. Dose-dependent radiation effects were comparable for alpha-emitters and both high- and low-energy electron emitters. The radioprotection by DMSO was not influenced by hypoxia. The results indicate the contribution of mainly indirect radiation effects for 99mTc, 188Re and 223Ra. 99mTc-labeled pyrene caused direct DNA damages and Auger-electrons from 99mTc-labeled pyrene are more effective than high-energy electrons or alpha particles. ADVANCES IN KNOWLEDGE: Without the consideration of DNA repair mechanisms, oxygen has no direct influence in radiation-induced DNA damages by different radiation qualities. IMPLICATIONS FOR PATIENT CARE: The short-time stimulation with oxygen during patient radiation could have minor influence compared to constant oxygen flooding to overcome hypoxic barriers.
INTRODUCTION: Radiation-induced DNA damage occurs from direct and indirect effects. The induction is influenced by the physical characteristics of the radionuclide, especially its linear energy transfer. Hypoxia reduces the effect of irradiation treatment in tumor cells and leads to poor patient outcomes. High linear energy transfer emitters can overcome this obstacle. Our aim is to demonstrate the influence of hypoxia on the interaction of different radiation qualities with isolated DNA. METHODS: PuC19 Plasmid DNA was irradiated with 223Ra, 188Re, 99mTc and 99mTc-labeled pyrene with and without DMSO under hypoxia or normoxic conditions. DNA damages in form of single-(SSB) and double-strand breaks (DSB) were analyzed by gel electrophoresis. RESULTS: Radiation doses up to 200 Gy of 223Ra, 188Re and 99mTc led to maximal yields of 80% SSB and 30%, 28% and 32% DSB, respectively. Hypoxia had minor effects on damages from 223Ra, but caused a small enhancement in DSB for 188Re and 99mTc. DMSO prevented DSB completely and reduced SSB from the "free" radionuclides to comparable levels. DNA-binding 99mTc-labeled pyrene induced less SSB and DSB compared to [99mTc]TcO4-. However, the incubation with DMSO could prevent the SSB and DSB induction only to a minor extent. CONCLUSIONS:Hypoxia does not limit DNA damage induced by 223Ra, 188Re, 99mTc and 99mTc-labeled pyrene. Dose-dependent radiation effects were comparable for alpha-emitters and both high- and low-energy electron emitters. The radioprotection by DMSO was not influenced by hypoxia. The results indicate the contribution of mainly indirect radiation effects for 99mTc, 188Re and 223Ra. 99mTc-labeled pyrene caused direct DNA damages and Auger-electrons from 99mTc-labeled pyrene are more effective than high-energy electrons or alpha particles. ADVANCES IN KNOWLEDGE: Without the consideration of DNA repair mechanisms, oxygen has no direct influence in radiation-induced DNA damages by different radiation qualities. IMPLICATIONS FOR PATIENT CARE: The short-time stimulation with oxygen during patient radiation could have minor influence compared to constant oxygen flooding to overcome hypoxic barriers.
Authors: Elise Verger; Jordan Cheng; Vittorio de Santis; Madeleine Iafrate; Jessica A Jackson; Cinzia Imberti; Gilbert O Fruhwirth; Philip J Blower; Michelle T Ma; Daniel R Burnham; Samantha Y A Terry Journal: Nucl Med Biol Date: 2021-06-15 Impact factor: 2.408