Program Information
Biological Geometries for the Monte Carlo Simulation Toolkit TOPAS-NBio
A McNamara1*, J Perl2 , P Piersimoni3 , J Ramos-Mendez3 , B Faddegon3 , K Held1 , H Paganetti1 , J Schuemann1 , (1) Massachusetts General Hospital & Harvard Med. Sch., Boston, MA, (2) Stanford Linear Accelerator Center, Menlo Park, CA, (3) University of California, San Francisco, San Francisco, CA.
Presentations
WE-H-BRA-4 (Wednesday, August 3, 2016) 4:30 PM - 6:00 PM Room: Ballroom A
Purpose:
New advances in radiation therapy are most likely to come from the complex interface of physics, chemistry and biology. Computational simulations offer a powerful tool for quantitatively investigating radiation interactions with biological tissue and can thus help bridge the gap between physics and biology. The aim of TOPAS-nBio is to provide a comprehensive tool to generate advanced radiobiology simulations.
Methods:
TOPAS wraps and extends the Geant4 Monte Carlo (MC) simulation toolkit. TOPAS-nBio is an extension to TOPAS which utilizes the physics processes in Geant4-DNA to model biological damage from very low energy secondary electrons. Specialized cell, organelle and molecular geometries were designed for the toolkit.
Results:
TOPAS-nBio gives the user the capability of simulating biological geometries, ranging from the micron-scale (e.g. cells and organelles) to complex nano-scale geometries (e.g. DNA and proteins). The user interacts with TOPAS-nBio through easy-to-use input parameter files. For example, in a simple cell simulation the user can specify the cell type and size as well as the type, number and size of included organelles. For more detailed nuclear simulations, the user can specify chromosome territories containing chromatin fiber loops, the later comprised of nucleosomes on a double helix. The chromatin fibers can be arranged in simple rigid geometries or within factual globules, mimicking realistic chromosome territories. TOPAS-nBio also provides users with the capability of reading protein data bank 3D structural files to simulate radiation damage to proteins or nucleic acids e.g. histones or RNA. TOPAS-nBio has been validated by comparing results to other track structure simulation software and published experimental measurements.
Conclusion:
TOPAS-nBio provides users with a comprehensive MC simulation tool for radiobiological simulations, giving users without advanced programming skills the ability to design and run complex simulations.
Contact Email: