We present a multi-scale approach of tumor modeling in order to predict its evolution during radiotherapy. Within this context we focus on three different scales of tumor modeling: microscopic (individual cells in a voxel), mesoscopic (population of cells in a voxel) and macroscopic (whole tumor), with transition interfaces between these three scales. At the cellular level, the description is based on phase transfer probabilities in the cellular cycle. At the mesoscopic scale we represent populations of cells according to different stages in a cell cycle. Finally, at the macroscopic scale, the tumor description is based on the use of FDG PET image voxels. These three scales exist naturally: biological data are collected at the macroscopic s...
Simulating cancer behavior across multiple biological scales in space and time, i.e., multiscale can...
<div><p>In this paper we use a hybrid multiscale mathematical model that incorporates both individua...
The temporal and spatial resolution in the microscopy of tissues has increased significa...
We present a multi-scale approach of tumor modeling in order to predict its evolution during radioth...
Despite the intensive use of radiotherapy in clinical practice, its effectiveness depends on several...
International audienceBACKGROUND: Radiotherapy outcomes are usually predicted using the Linear Quadr...
Summarization: Cancer mathematical modeling constitutes an emerging area of research aiming to predi...
The number of cancer related deaths is predicted to reach over 13.1 million in 2030. Understanding ...
Cancer is a complex disease, necessitating research on many different levels; at the subcellular lev...
Tumor heterogeneity can be observed between and within tumors through medical imaging such as positr...
Modeling of tumor growth has been performed according to various approaches addressing different bio...
Les travaux présentés dans le cadre de cette thèse ont porté sur la modélisation mathématique de la ...
In this paper we use a hybrid multiscale mathematical model that incorporates both individual cell b...
Despite major scientific, medical and technological advances over the last few decades, a cure for c...
Simulating cancer behavior across multiple biological scales in space and time, i.e., multiscale can...
<div><p>In this paper we use a hybrid multiscale mathematical model that incorporates both individua...
The temporal and spatial resolution in the microscopy of tissues has increased significa...
We present a multi-scale approach of tumor modeling in order to predict its evolution during radioth...
Despite the intensive use of radiotherapy in clinical practice, its effectiveness depends on several...
International audienceBACKGROUND: Radiotherapy outcomes are usually predicted using the Linear Quadr...
Summarization: Cancer mathematical modeling constitutes an emerging area of research aiming to predi...
The number of cancer related deaths is predicted to reach over 13.1 million in 2030. Understanding ...
Cancer is a complex disease, necessitating research on many different levels; at the subcellular lev...
Tumor heterogeneity can be observed between and within tumors through medical imaging such as positr...
Modeling of tumor growth has been performed according to various approaches addressing different bio...
Les travaux présentés dans le cadre de cette thèse ont porté sur la modélisation mathématique de la ...
In this paper we use a hybrid multiscale mathematical model that incorporates both individual cell b...
Despite major scientific, medical and technological advances over the last few decades, a cure for c...
Simulating cancer behavior across multiple biological scales in space and time, i.e., multiscale can...
<div><p>In this paper we use a hybrid multiscale mathematical model that incorporates both individua...
The temporal and spatial resolution in the microscopy of tissues has increased significa...