On Boolean gates in fungal colony

Andrew Adamatzky; Martin Tegelaar; Han A B Wosten; Anna L Powell; Alexander E Beasley; Richard Mayne

doi:10.1016/j.biosystems.2020.104138

On Boolean gates in fungal colony

Biosystems. 2020 Jun:193-194:104138. doi: 10.1016/j.biosystems.2020.104138. Epub 2020 Apr 4.

Authors

Andrew Adamatzky¹, Martin Tegelaar², Han A B Wosten², Anna L Powell³, Alexander E Beasley³, Richard Mayne⁴

Affiliations

¹ Unconventional Computing Laboratory, UWE, Bristol, UK. Electronic address: andrew.adamatzky@uwe.ac.uk.
² Microbiology Department, University of Utrecht, Utrecht, The Netherlands.
³ Unconventional Computing Laboratory, UWE, Bristol, UK.
⁴ Unconventional Computing Laboratory, UWE, Bristol, UK; Department of Applied Sciences, UWE, Bristol, UK.

PMID: 32259561
DOI: 10.1016/j.biosystems.2020.104138

Abstract

A fungal colony maintains its integrity via flow of cytoplasm along mycelium network. This flow, together with possible coordination of mycelium tips propagation, is controlled by calcium waves and associated waves of electrical potential changes. We propose that these excitation waves can be employed to implement a computation in the mycelium networks. We use FitzHugh-Nagumo model to imitate propagation of excitation in a single colony of Aspergillus niger. Boolean values are encoded by spikes of extracellular potential. We represent binary inputs by electrical impulses on a pair of selected electrodes and we record responses of the colony from sixteen electrodes. We derive sets of two-inputs-on-output logical gates implementable the fungal colony and analyse distributions of the gates.

Keywords: Boolean gates; Mycelium network; Unconventional computing.

MeSH terms

Aspergillus niger / genetics*
Colony Count, Microbial / methods*
Computer Simulation*
Cytoplasm / genetics
Gene Regulatory Networks*
Mycelium / genetics*