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Main Authors: Sabu, Nithin V., Unluturk, Bige Deniz
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.08926
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author Sabu, Nithin V.
Unluturk, Bige Deniz
author_facet Sabu, Nithin V.
Unluturk, Bige Deniz
contents Electrochemical communication is a mechanism that enables intercellular interaction among bacteria within communities. Bacteria achieves synchronization and coordinates collective actions at the population level through the utilization of electrochemical signals. In this work, we investigate the response of bacterial biofilms to artificial potassium concentration stimulation. We introduce signal inputs at a specific location within the biofilm and observe their transmission to other regions, facilitated by intermediary cells that amplify and relay the signal. We analyze the output signals when biofilm regions are subjected to different input signal types and explore their impact on biofilm growth. Furthermore, we investigate how the temporal gap between input pulses influences output signal characteristics, demonstrating that an appropriate gap yields distinct and well-defined output signals. Our research sheds light on the potential of bacterial biofilms as communication nodes in electrochemical communication networks.
format Preprint
id arxiv_https___arxiv_org_abs_2403_08926
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Electrochemical Communication in Bacterial Biofilms: A Study on Potassium Stimulation and Signal Transmission
Sabu, Nithin V.
Unluturk, Bige Deniz
Information Theory
Biological Physics
Electrochemical communication is a mechanism that enables intercellular interaction among bacteria within communities. Bacteria achieves synchronization and coordinates collective actions at the population level through the utilization of electrochemical signals. In this work, we investigate the response of bacterial biofilms to artificial potassium concentration stimulation. We introduce signal inputs at a specific location within the biofilm and observe their transmission to other regions, facilitated by intermediary cells that amplify and relay the signal. We analyze the output signals when biofilm regions are subjected to different input signal types and explore their impact on biofilm growth. Furthermore, we investigate how the temporal gap between input pulses influences output signal characteristics, demonstrating that an appropriate gap yields distinct and well-defined output signals. Our research sheds light on the potential of bacterial biofilms as communication nodes in electrochemical communication networks.
title Electrochemical Communication in Bacterial Biofilms: A Study on Potassium Stimulation and Signal Transmission
topic Information Theory
Biological Physics
url https://arxiv.org/abs/2403.08926