Low-dose-rate ionizing radiation increases singlet oxygen production by photosensitizers
Bing Xu (TU Delft - RST/Applied Radiation & Isotopes)
Juncheng Liu (TU Delft - RST/Applied Radiation & Isotopes)
Rienk Eelkema (TU Delft - ChemE/Advanced Soft Matter)
Antonia G. Denkova (TU Delft - RST/Applied Radiation & Isotopes)
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Abstract
Photosensitizers have significant potential as radiosensitizers in cancer treatment, yet the mechanism of ionizing-radiation-induced singlet oxygen (1O2) generation remains unclear. Here, we systematically investigated 1O2 production by the photosensitizer Chlorin e6 (Ce6) using the Singlet Oxygen Sensor Green probe and imidazole/ p -nitroso- N , N -dimethylaniline detection methods, evaluating the effects of photon energy (X-rays up to 310 kV and 60Co gamma rays at 1.17 and 1.33 MeV), dose, and dose rate. Ce6 produced more 1O2 with increasing photon energy. At 5 Gy, the lowest dose rate (0.005 Gy/min) yielded significantly more 1O2 than higher dose rates (7–0.05 Gy/min). Scavenging experiments identified superoxide anions (·O2−) as a key intermediate. We propose that, unlike classical triplet-state photosensitization, ionizing radiation induces Ce6 radical cations (Ce6⋅+), which react with radiation-induced ·O2− to generate 1O2. These findings suggest potential for photosensitizer-radiation combinations in low-dose-rate therapies, although further biological validation and consideration of tumor redox status are required.
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