Minimal model of a cell connecting amoebic motion and adaptive transport networks

Gunji, Yukio Pegio; Shirakawa, Tomohiro; Niizato, Takayuki; Haruna, Taichi

doi:10.1016/j.jtbi.2008.04.017

Cited by 68 publications

(81 citation statements)

References 24 publications

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“…By beginning with a complete network this method, although successful in generating impressive solutions to network problems, sidesteps the issue of initial network formation. Gunji et al (2008) introduced a cellular automaton (CA) model which considered both plasmodial growth and amoeboid movement. Their model placed importance on the transformation of hardness/softness at the membrane and the internal transport of material from the membrane resulting in movement and network adaptation.…”

Section: Introductionmentioning

confidence: 99%

Influences on the formation and evolution of Physarum polycephalum inspired emergent transport networks

Jones

2010

Nat Comput

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Section: Introductionmentioning

confidence: 99%

Influences on the formation and evolution of Physarum polycephalum inspired emergent transport networks

Jones

2010

Nat Comput

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“…Gunji et al introduced a cellular automaton (CA) model that considered both plasmodial growth and amoeboid movement [19]. Their model placed importance on the transformation between hardness and softness at the membrane and the internal transport of material from the membrane, resulting in movement and network adaptation.…”

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confidence: 99%

Characteristics of Pattern Formation and Evolution in Approximations of Physarum Transport Networks

Jones

2010

Artificial Life

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Most studies of pattern formation place particular emphasis on its role in the development of complex multicellular body plans. In simpler organisms, however, pattern formation is intrinsic to growth and behavior. Inspired by one such organism, the true slime mold Physarum polycephalum, we present examples of complex emergent pattern formation and evolution formed by a population of simple particle-like agents. Using simple local behaviors based on chemotaxis, the mobile agent population spontaneously forms complex and dynamic transport networks. By adjusting simple model parameters, maps of characteristic patterning are obtained. Certain areas of the parameter mapping yield particularly complex long term behaviors, including the circular contraction of network lacunae and bifurcation of network paths to maintain network connectivity. We demonstrate the formation of irregular spots and labyrinthine and reticulated patterns by chemoattraction. Other Turing-like patterning schemes were obtained by using chemorepulsion behaviors, including the self-organization of regular periodic arrays of spots, and striped patterns. We show that complex pattern types can be produced without resorting to the hierarchical coupling of reaction-diffusion mechanisms. We also present network behaviors arising from simple pre-patterning cues, giving simple examples of how the emergent pattern formation processes evolve into networks with functional and quasi-physical properties including tensionlike effects, network minimization behavior, and repair to network damage. The results are interpreted in relation to classical theories of biological pattern formation in natural systems, and we suggest mechanisms by which emergent pattern formation processes may be used as a method for spatially represented unconventional computation.

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“…This is time consuming. Cellular automaton models of the slime mould's foraging behaviour were proposed in [60,61]. Cellular automata are efficient in term of spatial and temporal complexity: the number of cell/node state are finite, typically less than a dozen, and size of a lattice usually does not exceed 500×500.…”

Section: Discussionmentioning

confidence: 99%

A Physarum-inspired approach to supply chain network design

Adamatzky

Yang

et al. 2016

Sci. China Inf. Sci.

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A supply chain is a system which moves products from a supplier to customers, which plays a very important role in all economic activities. This paper proposes a novel algorithm for a supply chain network design inspired by biological principles of nutrients' distribution in protoplasmic networks of slime mould Physarum polycephalum. The algorithm handles supply networks where capacity investments and product flows are decision variables, and the networks are required to satisfy product demands. Two features of the slime mould are adopted in our algorithm. The first is the continuity of flux during the iterative process, which is used in realtime updating of the costs associated with the supply links. The second feature is adaptivity. The supply chain can converge to an equilibrium state when costs are changed. Numerical examples are provided to illustrate the practicality and flexibility of the proposed method algorithm.

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Minimal model of a cell connecting amoebic motion and adaptive transport networks

Cited by 68 publications

References 24 publications

Influences on the formation and evolution of Physarum polycephalum inspired emergent transport networks

Influences on the formation and evolution of Physarum polycephalum inspired emergent transport networks

Characteristics of Pattern Formation and Evolution in Approximations of Physarum Transport Networks

A Physarum-inspired approach to supply chain network design

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