Turing Pattern Formation in Reaction-Cross-Diffusion Systems with a Bilayer Geometry

Diez, Antoine; Krause, Andrew L.; Maini, Philip K.; Gaffney, Eamonn A.; Seirin-Lee, Sungrim

doi:10.1007/s11538-023-01237-1

Cited by 3 publications

References 66 publications

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Well-Posedness Results for General Reaction–diffusion Transport of Oxygen in Encapsulated Cells

NAKAMURA,

PUTRI,

STERK

et al. 2024

Bull. Aust. Math. Soc.

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We provide well-posedness results for nonlinear parabolic partial differential equations (PDEs) given by reaction–diffusion equations describing the concentration of oxygen in encapsulated cells. The cells are described in terms of a core and a shell, which introduces a discontinuous diffusion coefficient as the material properties of the core and shell differ. In addition, the cells are subject to general nonlinear consumption of oxygen. As no monotonicity condition is imposed on the consumption, monotone operator theory cannot be used. Moreover, the discontinuity in the diffusion coefficient bars us from applying classical results on strong solutions. However, by directly applying a Galerkin method, we obtain uniqueness and existence of the strong form solution. These results provide the basis to study the dynamics of cells in critical states.

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Well-Posedness Results for General Reaction–diffusion Transport of Oxygen in Encapsulated Cells

NAKAMURA,

PUTRI,

STERK

et al. 2024

Bull. Aust. Math. Soc.

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Turing patterns on discrete topologies: from networks to higher-order structures

Muolo,

Giambagli,

Nakao

et al. 2024

Proc. R. Soc. A.

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Nature is a blossoming of regular structures, signature of self-organization of the underlying microscopic interacting agents. Turing theory of pattern formation is one of the most studied mechanisms to address such phenomena and has been applied to a widespread gallery of disciplines. Turing himself used a spatial discretization of the hosting support to eventually deal with a set of ODEs. Such an idea contained the seeds of the theory on discrete support, which has been fully acknowledged with the birth of network science in the early 2000s. This approach allows us to tackle several settings not displaying a trivial continuous embedding, such as multiplex, temporal networks and, recently, higher-order structures. This line of research has been mostly confined within the network science community, despite its inherent potential to transcend the conventional boundaries of the PDE-based approach to Turing patterns. Moreover, network topology allows for novel dynamics to be generated via a universal formalism that can be readily extended to account for higher-order structures. The interplay between continuous and discrete settings can pave the way for further developments in the field.

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Quantifying the intricacies of biological pattern formation: A new perspective through complexity measures

Riedel,

Barnes

2024

Preprint

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In this study we examine the emergence of complex biological patterns through the lens of reaction-diffusion systems. We introduce two novel complexity metrics, Diversity of Number of States (DNOS) and Diversity of Pattern Complexity (DPC), which aim to quantify structural intricacies in pattern formation, enhancing traditional linear stability analysis methods. We demonstrate this approach to different systems including the linear Turing, Gray-Scott and FitzHugh-Nagumo models. These measures reveal insights into nonlinear dynamics, multistability, and the conditions under which complex biological patterns stabilize. We then apply the approach to gene regulatory networks, including models of the toggle switch in developmental biology, demonstrating how diffusion and self-activation contribute to robust spatial patterning. Additionally, simulations of the Notch-Delta-EGF signaling pathway in Drosophila neurogenesis highlight the role of gene regulation and parameter variations in modulating pattern complexity and state diversity. Overall, this work establishes complexity-based approaches as valuable tools for exploring the conditions that drive diverse and stable biological pattern formation, offering a pathway for future applications in synthetic biology and tissue engineering.

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Turing Pattern Formation in Reaction-Cross-Diffusion Systems with a Bilayer Geometry

Cited by 3 publications

References 66 publications

Well-Posedness Results for General Reaction–diffusion Transport of Oxygen in Encapsulated Cells

Well-Posedness Results for General Reaction–diffusion Transport of Oxygen in Encapsulated Cells

Turing patterns on discrete topologies: from networks to higher-order structures

Quantifying the intricacies of biological pattern formation: A new perspective through complexity measures

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