TY - JOUR
T1 - Cellular-and micro-dosimetry of heterogeneously distributed tritium
AU - Chao, Tsi Chian
AU - Wang, Chun Ching
AU - Li, Junli
AU - Li, Chunyan
AU - Tung, Chuan Jong
PY - 2012/1
Y1 - 2012/1
N2 - Purpose: The assessment of radiotoxicity for heterogeneously distributed tritium should be based on the subcellular dose and relative biological effectiveness (RBE) for cell nucleus. In the present work, geometry-dependent absorbed dose and RBE were calculated using Monte Carlo codes for tritium in the cell, cell surface, cytoplasm, or cell nucleus. Materials and methods: Penelope (PENetration and Energy LOss of Positrins and Electrons) code was used to calculate the geometry-dependent absorbed dose, lineal energy, and electron fluence spectrum. RBE for the intestinal crypt regeneration was calculated using a lineal energy-dependent biological weighting function. RBE for the induction of DNA double strand breaks was estimated using a nucleotide-level map for clustered DNA lesions of the Monte Carlo damage simulation (MCDS) code. Results: For a typical cell of 10 μm radius and 5 μm nuclear radius, tritium in the cell nucleus resulted in much higher RBE-weighted absorbed dose than tritium distributed uniformly. Conversely, tritium distributed on the cell surface led to trivial RBE-weighted absorbed dose due to irradiation geometry and great attenuation of beta particles in the cytoplasm. For tritium uniformly distributed in the cell, the RBE-weighted absorbed dose was larger compared to tritium uniformly distributed in the tissue. Conclusions: Cellular-and micro-dosimetry models were developed for the assessment of heterogeneously distributed tritium.
AB - Purpose: The assessment of radiotoxicity for heterogeneously distributed tritium should be based on the subcellular dose and relative biological effectiveness (RBE) for cell nucleus. In the present work, geometry-dependent absorbed dose and RBE were calculated using Monte Carlo codes for tritium in the cell, cell surface, cytoplasm, or cell nucleus. Materials and methods: Penelope (PENetration and Energy LOss of Positrins and Electrons) code was used to calculate the geometry-dependent absorbed dose, lineal energy, and electron fluence spectrum. RBE for the intestinal crypt regeneration was calculated using a lineal energy-dependent biological weighting function. RBE for the induction of DNA double strand breaks was estimated using a nucleotide-level map for clustered DNA lesions of the Monte Carlo damage simulation (MCDS) code. Results: For a typical cell of 10 μm radius and 5 μm nuclear radius, tritium in the cell nucleus resulted in much higher RBE-weighted absorbed dose than tritium distributed uniformly. Conversely, tritium distributed on the cell surface led to trivial RBE-weighted absorbed dose due to irradiation geometry and great attenuation of beta particles in the cytoplasm. For tritium uniformly distributed in the cell, the RBE-weighted absorbed dose was larger compared to tritium uniformly distributed in the tissue. Conclusions: Cellular-and micro-dosimetry models were developed for the assessment of heterogeneously distributed tritium.
KW - Cellular S-value
KW - Lineal energy
KW - Monte Carlo damage simulation (MCDS) code
KW - Penetration and energy loss of positrins and electrons (Penelope) code
KW - Relative biological effectiveness
KW - Tritium
UR - http://www.scopus.com/inward/record.url?scp=84855367153&partnerID=8YFLogxK
U2 - 10.3109/09553002.2011.595876
DO - 10.3109/09553002.2011.595876
M3 - 文章
C2 - 21770699
AN - SCOPUS:84855367153
SN - 0955-3002
VL - 88
SP - 151
EP - 157
JO - International Journal of Radiation Biology
JF - International Journal of Radiation Biology
IS - 1-2
ER -