Influence of a perpendicular magnetic field on biological effectiveness of carbon-ion beams.
Taku InaniwaMasao SuzukiShinji SatoAkira NodaMasayuki MuramatsuYoshiyuki IwataNobuyuki KanematsuToshiyuki ShiraiKoji NodaPublished in: International journal of radiation biology (2019)
Purpose: Our previous study revealed that the application of a magnetic field longitudinal to a carbon-ion beam of 0.1 ≤ B//≤ 0.6 T enhances the biological effectiveness of the radiation. The purpose of this study is to experimentally verify whether the application of a magnetic field perpendicular to the beam also alters the biological effectiveness. Methods and materials: Most experimental conditions other than the magnetic field direction were the same as those used in the previous study to allow comparison of their results. Human cancer and normal cells were exposed to low (12 keV/μm) and high (50 keV/μm) linear energy transfer (LET) carbon-ion beams under the perpendicular magnetic fields of B⊥ = 0, 0.15, 0.3, or 0.6 T generated by a dipole magnet. The effects of the magnetic fields on the biological effectiveness were evaluated by clonogenic cell survival. Doses that would result in the survival of 10%, D10s, were determined for the exposures and analyzed using Student's t-tests. Results: For both cancer and normal cells treated by low- and high-LET carbon-ion beams, the D10s measured in the presence of the perpendicular magnetic fields of B⊥ ≥ 0.15 T were not statistically different (p ≫ .05) from the D10s measured in the absence of the magnetic fields, B⊥ = 0 T. Conclusions: Exposure of human cancer and normal cells to the perpendicular magnetic fields of B⊥ ≤ 0.6 T did not alter significantly the biological effectiveness of the carbon-ion beams, unlike the exposure to longitudinal magnetic fields of the same strength. Although the mechanisms underlying the observed results still require further exploration, these findings indicate that the influence of the magnetic field on biological effectiveness of the carbon-ion beam depends on the applied field direction with respect to the beam.
Keyphrases
- randomized controlled trial
- systematic review
- induced apoptosis
- molecularly imprinted
- papillary thyroid
- endothelial cells
- cell cycle arrest
- energy transfer
- endoplasmic reticulum stress
- squamous cell carcinoma
- squamous cell
- cross sectional
- signaling pathway
- cell death
- single cell
- radiation induced
- radiation therapy
- high resolution
- childhood cancer
- solid phase extraction