Add to ORKGThe growth of filamentous cells is modeled through the use of exact, nonlinear, elasticity theory for shells and membranes. The biomechanical model is able to capture the generic features of growth of a broad array of cells including actinomycetes, fungi, and root hairs. It also provides the means of studying the effects of external surface stresses. The growth mechanism is modeled by a process of incremental elastic growth in which the cell wall responds elastically to the continuous addition of new material. © Springer Science+Business Media B.V. 2010
Morphogenesis in plants and animals involves large irreversible deformations. In plants, the respons...
In this paper, we model the growth of single nonbranching fungal hypha cell. The growth proceeds as ...
The biomechanical modeling of growing tissues has recently become an area of intense interest. In pa...
The growth of filamentous cells is modeled through the use of exact, nonlinear, elasticity theory fo...
The mathematical modelling of growing filamentous cells has been approached in a variety of ways ran...
The tip growth of filamentary actinomycetes is investigated within the framework of large deformatio...
The growth of a family of filamentary microorganisms is described in terms of self-similar growth at...
Filamentous microorganisms, for example, fungi, experience polarized growth that the elongated filam...
In this paper we present a new model for single-celled, non-branching hypha tip growth. The growth m...
This chapter is concerned with the modelling of growth processes in the framework of continuum mecha...
International audienceA biomechanical model is proposed for the growth of the brown alga Ecto-carpus...
This paper is devoted to modelling tissue growth with a deformable cell model. Each cell represents ...
International audienceA biomechanical model is proposed for the growth of the brown alga Ecto-carpus...
A mathematical model for apical growth, septation, and branching of mycelial microorganisms is prese...
In life science, morphogenesis is the ensemble of biological processes that lead to the emergence of...
Morphogenesis in plants and animals involves large irreversible deformations. In plants, the respons...
In this paper, we model the growth of single nonbranching fungal hypha cell. The growth proceeds as ...
The biomechanical modeling of growing tissues has recently become an area of intense interest. In pa...
The growth of filamentous cells is modeled through the use of exact, nonlinear, elasticity theory fo...
The mathematical modelling of growing filamentous cells has been approached in a variety of ways ran...
The tip growth of filamentary actinomycetes is investigated within the framework of large deformatio...
The growth of a family of filamentary microorganisms is described in terms of self-similar growth at...
Filamentous microorganisms, for example, fungi, experience polarized growth that the elongated filam...
In this paper we present a new model for single-celled, non-branching hypha tip growth. The growth m...
This chapter is concerned with the modelling of growth processes in the framework of continuum mecha...
International audienceA biomechanical model is proposed for the growth of the brown alga Ecto-carpus...
This paper is devoted to modelling tissue growth with a deformable cell model. Each cell represents ...
International audienceA biomechanical model is proposed for the growth of the brown alga Ecto-carpus...
A mathematical model for apical growth, septation, and branching of mycelial microorganisms is prese...
In life science, morphogenesis is the ensemble of biological processes that lead to the emergence of...
Morphogenesis in plants and animals involves large irreversible deformations. In plants, the respons...
In this paper, we model the growth of single nonbranching fungal hypha cell. The growth proceeds as ...
The biomechanical modeling of growing tissues has recently become an area of intense interest. In pa...