We present a mechanical model for cell aggregation in embryonic development. The model is based on the large traction forces exerted by fibroblast cells which deform the extracellular matrix (ECM) on which they move. It is shown that the subsequent changes in the cell environment can combine to produce pattern. A linear analysis is carried out for this model. This reveals a wide spectrum of different types of dispersion relations. A non-linear bifurcation analysis is presented for a simple version of the field equations: a non-standard element is required. Biological applications are briefly discussed
The formation of self-organized patterns is key to the morphogenesis of multicellular organisms, alt...
<div><p>Geometric and mechanical properties of individual cells and interactions among neighboring c...
A tissue interaction model for skin organ pattern formation is presented. Possible spatially pattern...
We present a mechanical model for cell aggregation in embryonic development. The model is based on t...
In early embryonic development, fibroblast cells move through an extracellular matrix (ECM) exerting...
This paper studies a simplified but biologically relevant version of a mechanical model for morphoge...
We present a numerical study of the nonlinear mechanical model for morphogenesis proposed by Oster e...
There are two main modeling paradigms for biological pattern formation in developmental biology: che...
The early development of an animal results from a highly complex sequence of interactions within an...
AbstractA nonlinear reaction-diffusion model of pattern generation and morphogenesis during embryoni...
The diversity of biological form is generated by a relatively small number of underlying mechanisms....
The diversity of biological form is generated by a relatively small number of underlying mechanisms....
We present a numerical study of the nonlinear mechanical model for morphogenesis proposed by Oster e...
Many embryonic cells generate substantial contractile forces as they spread and crawl. These forces ...
During embryonic development, the behavior of individual cells must be coordinated to create the lar...
The formation of self-organized patterns is key to the morphogenesis of multicellular organisms, alt...
<div><p>Geometric and mechanical properties of individual cells and interactions among neighboring c...
A tissue interaction model for skin organ pattern formation is presented. Possible spatially pattern...
We present a mechanical model for cell aggregation in embryonic development. The model is based on t...
In early embryonic development, fibroblast cells move through an extracellular matrix (ECM) exerting...
This paper studies a simplified but biologically relevant version of a mechanical model for morphoge...
We present a numerical study of the nonlinear mechanical model for morphogenesis proposed by Oster e...
There are two main modeling paradigms for biological pattern formation in developmental biology: che...
The early development of an animal results from a highly complex sequence of interactions within an...
AbstractA nonlinear reaction-diffusion model of pattern generation and morphogenesis during embryoni...
The diversity of biological form is generated by a relatively small number of underlying mechanisms....
The diversity of biological form is generated by a relatively small number of underlying mechanisms....
We present a numerical study of the nonlinear mechanical model for morphogenesis proposed by Oster e...
Many embryonic cells generate substantial contractile forces as they spread and crawl. These forces ...
During embryonic development, the behavior of individual cells must be coordinated to create the lar...
The formation of self-organized patterns is key to the morphogenesis of multicellular organisms, alt...
<div><p>Geometric and mechanical properties of individual cells and interactions among neighboring c...
A tissue interaction model for skin organ pattern formation is presented. Possible spatially pattern...
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