Stability analysis of a state-dependent delay differential equation for cell maturation: analytical and numerical methods

In this paper we study the pseudospectral approximation of delay differential equations formulated as abstract differential equations in the *-space. This formalism also allows us to define rigorously the abstract variation-of-constants formula, where the *-shift operator plays a fundamental role. By applying the pseudospectral discretization technique we derive a system of ordinary differential equations, whose dynamics can be efficiently analyzed by existing bifurcation tools. To better understand to what extent the resulting finite-dimensional system "mimics" the dynamics of the original infinite-dimensional one, we study the pseudospectral approximations of the *-shift operator and of the *-generator in the supremum norm, which is the natural choice for delay differential equations, when the discretization parameter increases. In this context there are still open questions. We collect the most relevant results from the literature and we present some conjectures, supported by various numerical experiments, to illustrate the behavior w.r.t. the discretization parameter and to indicate the direction of ongoing and future research.

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“…where r M is defined in (32). We have that e M is a solution of (34) if and only if e M = Vz M with z M ∈ Y solution of the equation…”

Section: Pseudospectral Discretization Of Ddes In Sun-star Formulatiomentioning

confidence: 99%

“…Our aim is to survey what is known and to indicate possible future research directions, to obtain bounds in supremum norm in order to better understand to which extent the finite-dimensional ODE "mimics" the dynamics of the infinite-dimensional system described by the DDE. For some applications of the technique we refer to [2,8,9,32,37].…”

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confidence: 99%

Pseudospectral discretization of delay differential equations in <i>sun-star</i> formulation: Results and conjectures

Diekmann

Scarabel

Vermiglio

2020

Discrete &Amp; Continuous Dynamical Systems - S

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“…Some recent works have analysed the dynamics of the chemo-mechanical coupling through diffusion reaction equations, with applications in apical constriction in epithelia [11], monolayers on substrates [18,21] or wound healing [22]. In order to analyse the stability of such systems, we here focus on the delay and model it explicitly by resorting to a delayed cell rheology and the resulting delay differential equations, in similar manner to the stress analysis in yeast [13], neural axons conduction [3], transport in respiratory systems [5], or in cell maturation [10].…”

Section: Introductionmentioning

confidence: 99%

Effects of time delays and viscoelastic parameters in oscillatory response of cell monolayers

Borja

Moral

Romero

2021

Viscoelasticity and Collective Cell Migration

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Oscillatory response of cellular tissues has been observed in multiple embryogenetic developmental stages. The source of these oscillations has been attributed to imbalance of instabilities in the chemo-mechanical signalling and delayed cell activity. Although the relation of these oscillations with further drastic tissue deformation remains uncertain, it is apparent that intracellular remodelling events seem to drive the viscoelastic properties and the measured pulsatile deformations.We here resort to a viscoelastic model that is based on a variable restlength of the cell. We include a delay between the measured elastic strain and the evolution of the rest-length which dynamically adapts to the cell strain. This law is not only able to reproduce the relaxation phenomena observed in embryonic tissues in vitro and in vivo, but also to give rise to oscillatory cell responses. We analyse the stability of the resulting oscillations on minimal systems with two cells, and also on planar or out of plane deformation modes of monolayers. We conclude that in all cases, the stability decreases with an increasing delay or with the ability to adapt in a faster manner.

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“…The main focus of population dynamics has been a characterization of alterations in the numbers, sizes and age distribution of individuals and of potential internal or external causes provoking these changes. In the studies of structured population equations, linear semigroup methods were successfully developed to investigate the linear stability regularity and bifurcation phenomena of solutions for linearized systems, see [16,26,31,37]. The last years have witnessed an invigorated interest in age/size-structured population dynamics due to the wide applications.…”

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confidence: 99%

Long-time behavior of a size-structured population model with diffusion and delayed birth process

Yan

2022

EECT

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This work focuses on the long time behavior for a size-dependent population system with diffusion and Riker type birth function. Some dynamical properties of the considered system is investigated by using C 0 -semigroup theory and spectral analysis arguments. Some sufficient conditions are obtained respectively for asymptotical stability, asynchronous exponential growth at the null equilibrium as well as Hopf bifurcation occurring at the positive steady state of the system. In the end several examples and their simulations are also provided to illustrate the achieved results.

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Stability analysis of a state-dependent delay differential equation for cell maturation: analytical and numerical methods

Cited by 20 publications

References 57 publications

Pseudospectral discretization of delay differential equations in <i>sun-star</i> formulation: Results and conjectures

Pseudospectral discretization of delay differential equations in <i>sun-star</i> formulation: Results and conjectures

Effects of time delays and viscoelastic parameters in oscillatory response of cell monolayers

Long-time behavior of a size-structured population model with diffusion and delayed birth process

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