2017
DOI: 10.1002/cphc.201700477
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Computing in Verotoxin

Abstract: We develop an excitable automata model of a protein verotoxin and demonstrate that logic gates and circuits are realised in the model via interacting patterns of excitation. By sampling potential input pairs of nodes, we calculate frequencies of logic gates which occurred in the verotoxin model for various parameters of node excitation rules. We show that overall the gates can be arranged in the following hierarchy of descending frequencies: AND>OR>AND‐NOT>XOR. We demonstrate realisations of one‐bit half‐adder… Show more

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Cited by 13 publications
(16 citation statements)
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“…The distribution demonstrates frequencies of discoveries of the fourinput-one-output logical gates and could be used for characterisation of a computational power of the fungal substrates. This is accompanied by distributions of gates discovered in experimental laboratory reservoir computing with slime mould Physarum polycephalum [18], succulent plant [8] and numerical modelling experiments on computing with protein verotoxin [3], actin bundles network [9], and actin monomer [4]. The distributions of gates discovered in natural systems are alike to each other in the hierarchies of the gates frequencies.…”
Section: Spikes Derived Logical Gatesmentioning
confidence: 90%
See 1 more Smart Citation
“…The distribution demonstrates frequencies of discoveries of the fourinput-one-output logical gates and could be used for characterisation of a computational power of the fungal substrates. This is accompanied by distributions of gates discovered in experimental laboratory reservoir computing with slime mould Physarum polycephalum [18], succulent plant [8] and numerical modelling experiments on computing with protein verotoxin [3], actin bundles network [9], and actin monomer [4]. The distributions of gates discovered in natural systems are alike to each other in the hierarchies of the gates frequencies.…”
Section: Spikes Derived Logical Gatesmentioning
confidence: 90%
“…Figure 6. Comparative ratios of Boolean gates discovered in mycelium network analysed in present paper, black disc and solid line; slime mould Physarum polycephalum[18], black circle and dotted line; succulent plant[8], red snowflake and dashed line; single molecule of protein verotoxin[3], light blue '+' and dash-dot line; actin bundles network[9], green triangle pointing right and dash-dot-dot line; actin monomer[4], magenta triangle pointing left and dashed line. Area of xor gate is magnified in the insert.…”
mentioning
confidence: 85%
“…9. This is accompanied by distributions of gates discovered in experimental laboratory reservoir computing with slime mould Physarum polycephalum [34], succulent plant [11] and numerical modelling experiments on computing with protein verotoxin [2], actin bundles network [12], and actin monomer [3]. All the listed distributions have very similar structure with gates selecting one of the inputs in majority, followed by or gate, not-and an and-not gates.…”
Section: Distribution Of Boolean Gatesmentioning
confidence: 99%
“…Most close to biophysical reality models of computing on biological networks have been implemented with molecular structures of verotoxin protein [2] and actin monomer [3], actin bundles networks derived from experimental laboratory data [6], plant leaf vascular system [4] and microscopic images of three-dimensional fungal colonies [7]. These approaches employed the following method.…”
Section: Introductionmentioning
confidence: 99%