Cross-Section-Based Scaling Method for Material-Specific Cluster Dose Calculations -- A Proof of Concept

TL;DR

This paper presents a new material-specific scaling method for cluster dose calculations in track structure simulations, addressing the limitations of previous mass-density-based approaches and enabling more accurate dose estimations in heterogeneous tissues.

Contribution

It introduces a cross-section-based scaling method using ionization cross-sections and mean free path ratios, improving physical realism in dose calculations for different materials.

Findings

The new scaling method yields higher cluster dose values in denser materials.

It demonstrates improved physical consistency over traditional mass-density scaling.

The approach is applicable to heterogeneous geometries in radiotherapy planning.

Abstract

Cross-section data unavailability for non-water materials in track structure simulation software necessitates nanodosimetric quantity transformation from water to other materials. Cluster dose calculation transformation initially employed mass-density-based scaling - an approach resulting in a physically unrealistic material-independence of the cluster dose equation. This study introduces an alternative scaling method based on material-specific ionization cross-sections. The mean free path ratio of the materials for both the primary particles of the track structure simulation and for the secondary electrons served as the scaling factor. The approach was demonstrated through a cluster dose calculation for a carbon ion beam in a realistic head geometry and compared to the previous scaling method. The proposed cross-section-based scaling method resulted in a physically expected increase in cluster dose values for denser materials, which was not visible in the original scaling approach. The introduced scaling approach can be used to determine cluster dose distributions in heterogeneous geometries, a fundamental requirement for its integration into radiotherapy treatment planning frameworks.