The BIANCA biophysical model of cell death and chromosome aberrations was further refined and applied to predict the biological effectiveness along Spread-Out Bragg Peaks used in hadrontherapy. The simulation outcomes were compared with in vitro survival data on protons, He-ions and C-ions over a wide LET range, and the particle- and LET-dependence of the DNA Cluster Lesions (CLs) yields used as input parameters was investigated. For each particle type, the CL yield was found to increase with LET in a linear-quadratic fashion; fitting the CL yields allowed to predict cell death and chromosome aberrations in principle at any depth along a longitudinal proton dose profile used at CNAO. A clear increase in effectiveness was found in the SOBP distal region, supporting the idea that, in some cases, the constant proton RBE usually applied in clinics may be a sub-optimal solution.
Predicting biological effects along hadrontherapy dose profiles by the BIANCA biophysical model
Carante M. P.
;Tello J.;Ballarini F.
2019-01-01
Abstract
The BIANCA biophysical model of cell death and chromosome aberrations was further refined and applied to predict the biological effectiveness along Spread-Out Bragg Peaks used in hadrontherapy. The simulation outcomes were compared with in vitro survival data on protons, He-ions and C-ions over a wide LET range, and the particle- and LET-dependence of the DNA Cluster Lesions (CLs) yields used as input parameters was investigated. For each particle type, the CL yield was found to increase with LET in a linear-quadratic fashion; fitting the CL yields allowed to predict cell death and chromosome aberrations in principle at any depth along a longitudinal proton dose profile used at CNAO. A clear increase in effectiveness was found in the SOBP distal region, supporting the idea that, in some cases, the constant proton RBE usually applied in clinics may be a sub-optimal solution.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
