AIM: In this study, we investigated γH2AX foci as markers of DSBs in normal brain and brain tumor tissue in mouse after BNCT. BACKGROUND: Boron neutron capture therapy (BNCT) is a particle radiation therapy in combination of thermal neutron irradiation and boron compound that specifically accumulates in the tumor. (10)B captures neutrons and produces an alpha ((4)He) particle and a recoiled lithium nucleus ((7)Li). These particles have the characteristics of extremely high linear energy transfer (LET) radiation and therefore have marked biological effects. High LET radiation causes severe DNA damage, DNA DSBs. As the high LET radiation induces complex DNA double strand breaks (DSBs), large proportions of DSBs are considered to remain unrepaired in comparison with exposure to sparsely ionizing radiation. MATERIALS AND METHODS: We analyzed the number of γH2AX foci by immunohistochemistry 30 min or 24 h after neutron irradiation. RESULTS: In both normal brain and brain tumor, γH2AX foci induced by (10)B(n,α)(7)Li reaction remained 24 h after neutron beam irradiation. In contrast, γH2AX foci produced by γ-ray irradiation at contaminated dose in BNCT disappeared 24 h after irradiation in these tissues. CONCLUSION: DSBs produced by (10)B(n,α)(7)Li reaction are supposed to be too complex to repair for cells in normal brain and brain tumor tissue within 24 h. These DSBs would be more difficult to repair than those by γ-ray. Excellent anti-tumor effect of BNCT may result from these unrepaired DSBs induced by (10)B(n,α)(7)Li reaction.
AIM: In this study, we investigated γH2AX foci as markers of DSBs in normal brain and brain tumor tissue in mouse after BNCT. BACKGROUND:Boron neutron capture therapy (BNCT) is a particle radiation therapy in combination of thermal neutron irradiation and boron compound that specifically accumulates in the tumor. (10)B captures neutrons and produces an alpha ((4)He) particle and a recoiled lithium nucleus ((7)Li). These particles have the characteristics of extremely high linear energy transfer (LET) radiation and therefore have marked biological effects. High LET radiation causes severe DNA damage, DNA DSBs. As the high LET radiation induces complex DNA double strand breaks (DSBs), large proportions of DSBs are considered to remain unrepaired in comparison with exposure to sparsely ionizing radiation. MATERIALS AND METHODS: We analyzed the number of γH2AX foci by immunohistochemistry 30 min or 24 h after neutron irradiation. RESULTS: In both normal brain and brain tumor, γH2AX foci induced by (10)B(n,α)(7)Li reaction remained 24 h after neutron beam irradiation. In contrast, γH2AX foci produced by γ-ray irradiation at contaminated dose in BNCT disappeared 24 h after irradiation in these tissues. CONCLUSION:DSBs produced by (10)B(n,α)(7)Li reaction are supposed to be too complex to repair for cells in normal brain and brain tumor tissue within 24 h. These DSBs would be more difficult to repair than those by γ-ray. Excellent anti-tumor effect of BNCT may result from these unrepaired DSBs induced by (10)B(n,α)(7)Li reaction.
Entities:
Keywords:
Boron neutron capture therapy; DSBs; High LET radiation; γH2AX foci
Authors: Thomas E Schmid; Günther Dollinger; Wolfgang Beisker; Volker Hable; Christoph Greubel; Susanne Auer; Anja Mittag; Attila Tarnok; Anna A Friedl; Michael Molls; Barbara Röper Journal: Int J Radiat Biol Date: 2010-08 Impact factor: 2.694
Authors: Doug W Chan; Benjamin Ping-Chi Chen; Sheela Prithivirajsingh; Akihiro Kurimasa; Michael D Story; Jun Qin; David J Chen Journal: Genes Dev Date: 2002-09-15 Impact factor: 11.361