Development of a coupled simulation toolkit for computational radiation biology based on Geant4 and CompuCell3D

Liu, Ruirui; Higley, Kathryn A.; Swat, Maciej; Chaplain, M. A. J.; Powathil, Gibin; Glazier, James A.

doi:10.1088/1361-6560/abd4f9

Cited by 7 publications

(8 citation statements)

References 57 publications

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“…Hereby the prediction of cell-survival is the benchmark for testing new models [232]. Going beyond isolated cells to study phenomena such as the radiation induced bystander effect [222] or the radiation response on a tissue level [223] are still in an early stage. However, complete multiscale models including AuNP radiosensitization of DNA into a xenograft mouse model highlight already what can be achieved by integration and combination of simulation and modelling techniques on different scales [258].…”

Section: Discussionmentioning

confidence: 99%

“…Their term refers to cells which die or show choromosomal instability without having been directly irradiated during a treatment, as observed by Nagasawa and Little [219] after subjecting Chinese hamster ovary cells (CHO) to low doses of alpha particles, or by Sedelnikova et al which found DSB in bystander cells after irradiation of a human tissue models by a microbeam [220]. To study these effects with a multi-scale approach Geant4 and CompuCell3D [221] were combined by Liu et al via a newly developed bridging module named RADCELL [222]. This allowed them to combined simulations of cell biology and particlescattering simulations to study and quantifying cell behavior after irradiation.…”

Section: Cells and Their Organellesmentioning

confidence: 99%

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Accessing radiation damage to biomolecules on the nanoscale by particle-scattering simulations

Hahn

2023

J. Phys. Commun.

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Radiation damage to DNA plays a central role in radiation therapy to cure cancer. The physico-chemical and biological processes involved encompass huge time and spatial scales. To obtain a comprehensive understanding on the nano and the macro scale is a very challenging tasks for experimental techniques alone. Therefore particle-scattering simulations are often applied to complement measurements and aide their interpretation, to help in the planning of experiments, to predict their outcome and to test damage models. In the last years, powerful multipurpose particle-scattering framework based on the Monte-Carlo simulation (MCS) method, such as Geant4 and Geant4-DNA, were extended by user friendly interfaces such as TOPAS and TOPAS-nBio. This shifts their applicability from the realm of dedicated specialists to a broader range of scientists. In the present review we aim to give an overview over MCS based approaches to understand radiation interaction on a broad scale, ranging from cancerous tissue, cells and their organelles including the nucleus, mitochondria and membranes, over radiosensitizer such as metallic nanoparticles, and water with additional radical scavenger, down to isolated biomolecules in the form of DNA, RNA, proteins and DNA-protein complexes. Hereby the degradation of biomolecules by direct damage from inelastic scattering processes during the physical stage, and the indirect damage caused by radicals during the chemical stage as well as some parts of the early biological response is covered. Due to their high abundance the action of hydroxyl radicals (•OH) and secondary low energy electrons (LEE) as well as prehydrated electrons are covered in additional detail. Applications in the prediction of DNA damage, DNA repair processes, cell survival and apoptosis, influence of radiosensitizer on the dose distribution within cells an their organelles, the study of linear-energy-transfer (LET), the relative-biological-effectiveness (RBE), ion-beam cancer-therapy, microbeam-radiation-therapy (MRT), the FLASH effect, and the radiation induced bystander effect are reviewed.

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Section: Discussionmentioning

confidence: 99%

Section: Cells and Their Organellesmentioning

confidence: 99%

Accessing radiation damage to biomolecules on the nanoscale by particle-scattering simulations

Hahn

2023

J. Phys. Commun.

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“…One is the GEANT4-DNA code, a low-energy extension of GEANT4 that enables studies of the cellular radiobiological effects of ionizing radiation on DNA, considering the physical, chemical, and biological stages of the interactions. GEANT4 has also been coupled to the CompuCell3D cell biology simulation platform via the RADCELL module [85], enabling tumor geometries to be ported to the transport code. The ion stopping powers in various materials are key inputs for these codes.…”

Section: Electronics and Human Effectsmentioning

confidence: 99%

Nuclear Data for High Energy Ion Interactions and Secondary Particle Production

Smith

Vogt

LaBel

2022

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Understanding the harmful effects of galactic cosmic rays (GCRs) on space exploration requires a substantial amount of nuclear data. Specifically, the interaction of energetic GCR charged particles with spacecraft materials generates secondary radiations that, through energy deposition, can harm astronauts and electronic systems. By identifying the gaps in our knowledge of the relevant nuclear data -such as interaction cross sections -and identifying ways to fill those gaps -with measurements, compilations, evaluations, dissemination, reaction modeling, sensitivity studies, and uncertainty quantification -the safety and viability of space exploration can be improved. This work surveys the state of the art in this interdisciplinary field and identifies promising collaborative research topics that have significant potential to advance our understanding of the effects of the space radiation environment on space exploration.

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“…Outside of plant world other frameworks could be adapted to model plant organs such as CompuCell3D ( Cickovski et al, 2005 ) – a lattice-based multicellular modeling environment to simulate tissue formation by merging the CPM with chemical fields and diffusion equations. CompuCell3D functionalities have been demonstrated in the context of animal embryogenesis, cell population dynamics, tumor formation, and many more ( Andasari et al, 2012 ; Swat et al, 2012 ; Fortuna et al, 2020 ; Liu et al, 2021 ). Another valuable tool to simulate animal embryogenesis is MecaGen, a C++ simulation platform of animal multicellular development relying on mechanistic agent-based models ( Delile et al, 2017 ).…”

Section: Survey Of Mechanical and Biochemical Modeling Frameworkmentioning

confidence: 99%

Shaping the Organ: A Biologist Guide to Quantitative Models of Plant Morphogenesis

Marconi

Wabnik

2021

Front. Plant Sci.

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Organ morphogenesis is the process of shape acquisition initiated with a small reservoir of undifferentiated cells. In plants, morphogenesis is a complex endeavor that comprises a large number of interacting elements, including mechanical stimuli, biochemical signaling, and genetic prerequisites. Because of the large body of data being produced by modern laboratories, solving this complexity requires the application of computational techniques and analyses. In the last two decades, computational models combined with wet-lab experiments have advanced our understanding of plant organ morphogenesis. Here, we provide a comprehensive review of the most important achievements in the field of computational plant morphodynamics. We present a brief history from the earliest attempts to describe plant forms using algorithmic pattern generation to the evolution of quantitative cell-based models fueled by increasing computational power. We then provide an overview of the most common types of “digital plant” paradigms, and demonstrate how models benefit from diverse techniques used to describe cell growth mechanics. Finally, we highlight the development of computational frameworks designed to resolve organ shape complexity through integration of mechanical, biochemical, and genetic cues into a quantitative standardized and user-friendly environment.

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Development of a coupled simulation toolkit for computational radiation biology based on Geant4 and CompuCell3D

Cited by 7 publications

References 57 publications

Accessing radiation damage to biomolecules on the nanoscale by particle-scattering simulations

Accessing radiation damage to biomolecules on the nanoscale by particle-scattering simulations

Nuclear Data for High Energy Ion Interactions and Secondary Particle Production

Shaping the Organ: A Biologist Guide to Quantitative Models of Plant Morphogenesis

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