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References (52)
-
I. Barrantes, Gernot Glockner, S. Meyer, W. Marwan (2010)
Transcriptomic changes arising during light-induced sporulation in Physarum polycephalumBMC Genomics, 11
-
A. Dussutour, T. Latty, M. Beekman, S. Simpson (2010)
Amoeboid organism solves complex nutritional challengesProceedings of the National Academy of Sciences, 107
-
Richard Mayne, Michail-Antisthenis Tsompanas, G. Sirakoulis, A. Adamatzky (2015)
Towards a slime Mould-FPGA interfaceBiomedical Engineering Letters, 5
-
O. Anderson (1993)
Fine Structure Observations of Phagotrophic Activity By Plasmodia of Physarum PolycephalumJournal of Eukaryotic Microbiology, 40
-
E. Goodman, B. Greenebaum, M. Marron (1979)
Bioeffects of extremely low-frequency electromagnetic fields. Variation with intensity, waveform, and individual or combined electric and magnetic fields.Radiation research, 78 3
-
W. Gray, C. Alexopoulos (1969)
Biology of the myxomycetesBulletin of the Torrey Botanical Club, 96
-
J. Daniel, H. Rusch (1961)
The pure culture of Physarum polycephalum on a partially defined soluble medium.Journal of general microbiology, 25
-
T. Shirakawa, Ryusuke Konagano, Keita Inoue (2012)
Novel taxis of the Physarum plasmodium and a taxis-based simulation of Physarum swarmThe 6th International Conference on Soft Computing and Intelligent Systems, and The 13th International Symposium on Advanced Intelligence Systems
-
W. Wormington, R. Weaver (1976)
Photoreceptor pigment that induces differentiation in the slime mold Physarum polycephalum.Proceedings of the National Academy of Sciences of the United States of America, 73 11
-
A. Adamatzky (2009)
Steering plasmodium with light: Dynamical programming of Physarum machineArXiv, abs/0908.0850
-
Tetsuo Ueda, K. Olenhusen (1978)
Replacement of endoplasm with artificial media in plasmodial strands of Physarum polycephalum. Effects on contractility and morphology.Experimental cell research, 116 1
-
Robert Rhea (1966)
Electron microscopic observations on the slime mold Physarum polycephalum with specific reference to fibrillar structures.Journal of ultrastructure research, 15 3
-
K. Wohlfarth-Bottermann (1979)
Oscillatory contraction activity in Physarum.The Journal of experimental biology, 81
-
I. Tasaki, N. Kamiya (1950)
Electrical response of a slime mold to mechanical and electrical stimuliProtoplasma, 39
-
E. Guttes, S. Guttes (1960)
Pinocytosis in the myxomycete Physarum polycephalum.Experimental cell research, 20
-
Richard Mayne, A. Adamatzky (2015)
Slime mould foraging behaviour as optically coupled logical operationsInternational Journal of General Systems, 44
-
M. Ishigami, K. Kuroda, S. Hatano (1987)
Dynamic aspects of the contractile system in Physarum plasmodium. III. Cyclic contraction-relaxation of the plasmodial fragment in accordance with the generation-degeneration of cytoplasmic actomyosin fibrilsThe Journal of Cell Biology, 105
-
K. Olenhusen, K. Wohlfarth-Bottermann (1979)
Evidence for actin transformation during the contraction-relaxation cycle of cytoplasmic actomyosin: Cycle blockade by Phalloidin injectionCell and Tissue Research, 196
-
Richard Mayne, A. Adamatzky (2015)
Toward Hybrid Nanostructure-Slime Mould Devices, 05
-
S. Githens, M. Karnovsky (1973)
PHAGOCYTOSIS BY THE CELLULAR SLIME MOLD POLYSPHONDYLIUM PALLIDUM DURING GROWTH AND DEVELOPMENTThe Journal of Cell Biology, 58
-
M. Hato, T. Ueda, K. Kurihara, Y. Kobatake (1976)
Phototaxis in true slime mold Physarum polycephalumCell Structure and Function, 1
-
A. Grębecki, M. Cieślawska (1978)
Plasmodium of Physarum polycephalum as a synchronous contractile system.Cytobiologie, 17 2
-
A. Adamatzky, B. Costello (2012)
© 2012 Landes Bioscience. Do not distribute. Physarum attraction: Why slime mold behaves as cats do? -
A. Adamatzky, T. Schubert (2014)
Slime mold microfluidic logical gatesMaterials Today, 17
-
A. Adamatzky (2013)
Towards slime mould colour sensor: Recognition of colours by Physarum polycephalumArXiv, abs/1312.4139
-
Richard Mayne, David Patton, B. Costello, A. Adamatzky, R. Patton (2011)
On the Internalisation, Intraplasmodial Carriage and Excretion of Metallic Nanoparticles in the Slime Mould, Physarum PolycephalumInt. J. Nanotechnol. Mol. Comput., 3
-
Gilles Faÿ, E. Moulines, François Roueff, Murad Taqqu (2009)
Características inmunológicas claves en la fisiopatología de la sepsis. InfectioEconometrics, 151
-
Toshiyuki Nakagaki, Hiroyasu Yamada, Tetsuo Ueda (2000)
Interaction between cell shape and contraction pattern in the Physarum plasmodium.Biophysical chemistry, 84 3
-
A. Adamatzky (2013)
Physarum wires: Self-growing self-repairing smart wires made from slime mouldBiomedical Engineering Letters, 3
-
A. Adamatzky (2011)
On attraction of slime mould Physarum polycephalum to plants with sedative propertiesNature Precedings, 6
-
K. Wohlfarth-Bottermann (1974)
Plasmalemma invaginations as characteristic constituents of plasmodia of Physarum polycephalum.Journal of cell science, 16 1
-
E. Goodman (1972)
Axenic Culture of Myxamoebae of the Myxomycete Physarum polycephalumJournal of Bacteriology, 111
-
C. Reid, T. Latty, A. Dussutour, M. Beekman (2012)
Slime mold uses an externalized spatial “memory” to navigate in complex environmentsProceedings of the National Academy of Sciences, 109
-
B. Costello, A. Adamatzky (2013)
Assessing the chemotaxis behavior of Physarum polycephalum to a range of simple volatile organic chemicalsCommunicative & Integrative Biology, 6
-
Richard Mayne, A. Adamatzky (2015)
On the Computing Potential of Intracellular VesiclesPLoS ONE, 10
-
A. Adamatzky (2007)
Physarum machines: encapsulating reaction–diffusion to compute spanning treeNaturwissenschaften, 94
-
A. Adamatzky (2010)
Manipulating substances with Physarum polycephalumMaterials Science and Engineering: C, 30
-
A. Adamatzky, J. Jones (2010)
ON ELECTRICAL CORRELATES OF PHYSARUM POLYCEPHALUM SPATIAL ACTIVITY: CAN WE SEE PHYSARUM MACHINE IN THE DARK?Biophysical Reviews and Letters, 06
-
A. Adamatzky (2013)
Slime mould tactile sensorArXiv, abs/1306.0258
-
C. McCullough, J. Dee (1976)
Defined and semi-defined media for the growth of amoebae of Physarum polycephalum.Journal of general microbiology, 95 1
-
J. Anderson (1951)
GALVANOTAXIS OF SLIME MOLDThe Journal of General Physiology, 35
-
P. Janmey (1998)
The cytoskeleton and cell signaling: component localization and mechanical coupling.Physiological reviews, 78 3
-
J. Jones (2015)
From Pattern Formation to Material Computation: Multi-agent Modelling of Physarum Polycephalum -
S. Yoshiyama, M. Ishigami, A. Nakamura, K. Kohama (2009)
Calcium wave for cytoplasmic streaming of Physarum polycephalumCell Biology International, 34
-
T. Nakagaki, Hiroyasu Yamada, Á. Tóth (2001)
Path finding by tube morphogenesis in an amoeboid organism.Biophysical chemistry, 92 1-2
-
L. Olive (2008)
The Mycetozoa: A revised classificationThe Botanical Review, 36
-
J. Fingerle, D. Gradmann (2005)
Electrical properties of the plasma membrane of microplasmodia ofPhysarum polycephalumThe Journal of Membrane Biology, 68
-
R. Wayne (2010)
Chapter 16 – The Nucleus -
A. Fiore-Donno, S. Nikolaev, M. Nelson, J. Pawłowski, T. Cavalier-smith, S. Baldauf (2010)
Deep phylogeny and evolution of slime moulds (mycetozoa).Protist, 161 1
-
T. Iwamura (1949)
Correlations between protoplasmic streaming and bioelectric potential of a slime mold, Physarum polycephalum, 62
-
S. Geroulanos, C. Panaretos, Efterpi Lyberopoulou (2014)
Surgery in Byzantium -
A. Adamatzky (2010)
Physarum Machines: Computers from Slime Mould
- Publisher
- Springer International Publishing
- Copyright
- © Springer International Publishing Switzerland 2016
- ISBN
- 978-3-319-26661-9
- Pages
- 3 –22
- DOI
- 10.1007/978-3-319-26662-6_1
- Publisher site
- See Chapter on Publisher Site
Abstract
[Slime mould Physarum polycephalum is a macroscopic amoeba-like organism whose ability to ‘compute’ the solutions to complex problems ranging from logic to computational geometry has led to its extensive use as an unconventional computing substrate. In slime mould computing devices—‘Physarum machines’—data may be imparted to the organism via stimulation with chemical, optical, mechanical or electrical sources and outputs are generally behavioural, chemical or/and electrical. This chapter examines the biological basis of a slime mould’s ability to perceive and act upon input data and the mechanisms that contribute towards the output we interpret as computation. Furthermore, various research methods for slime mould cultivation, electrophysiological measurement and hybridisation with exogenous substances are discussed. The data presented here provides an essential foundation for the computer scientist wishing to fabricate their own Physarum machines.]
Published: Jan 10, 2016
Keywords: Slime Mould; Physarum Polycephalum; Life Cycle Phase; Cellular Slime Mould; Swarm Cell