Fungal Tissue as a Medium for Electrical Signal Transmission: A Baseline Assessment With Melanized Fungus Curvularia Lunata

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Journal of Electromagnetics RF and Microwaves in Medicine and Biology Pub Date : 2024-10-16 DOI:10.1109/JERM.2024.3476444

Robert M. Jones;Randall W. Reynolds;Alison K. Thurston;Robyn A. Barbato

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Abstract

Fungal tissues are an underexplored medium for data and electrical signal transmission. Fungal tissues are a biodegradable material that can be cultivated in mass quantities; potentially making them sustainable materials for biological sensors or as a communication medium. Because the interactions of fungal tissues with communications signals are not thoroughly explored, a baseline assessment of the signal transmission capabilities of mat forming filamentous fungus, Curvularia lunata (C. lunata) was performed. In this paper, the band-pass characteristics of C. lunata were assessed through a frequency sweep from 1 Hz–5 MHz. The potential data transmission rates through a raw bit error rate analysis using a pseudorandom bit sequence between 1–1,000 kbps were evaluated. The passband for the tissue was between 1–500 kHz, characterizing it as a low-pass filter. Bit streams below 10 kbps had an error rate of <10%>500 kbps. The results suggest that this fungal tissue could serve as a low-speed data transmission medium specifically for low-pass signals related to general human health such as ECG, EEG, EMG signals as well as temperature and glucose monitoring. While more research is necessary to understand the morphological and species-specific impacts on signal propagation between different fungi, tissues from the fungus C. lunata and those with similar properties could potentially serve as a component in low-frequency biosensors and signal transmission.

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真菌组织作为电信号传输的媒介：黑化真菌弯孢菌的基线评估

真菌组织是一种未被充分开发的数据和电信号传输介质。真菌组织是一种可生物降解的材料，可以大量培养；有可能使它们成为生物传感器的可持续材料或作为通信媒介。由于真菌组织与通信信号的相互作用尚未被彻底探索，因此对形成垫子的丝状真菌弧形菌（C. lunata）的信号传输能力进行了基线评估。在本文中，通过1 Hz-5 MHz的频率扫描来评估月牙草的带通特性。通过使用1-1,000 kbps之间的伪随机比特序列进行原始误码率分析，评估了潜在的数据传输速率。该组织的通带在1-500 kHz之间，表征为低通滤波器。低于10kbps的比特流错误率为500kbps。结果表明，这种真菌组织可以作为一种低速数据传输介质，专门用于与一般人体健康相关的低通信号，如ECG、EEG、EMG信号以及温度和血糖监测。虽然需要更多的研究来了解不同真菌之间形态和物种特异性对信号传播的影响，但来自真菌C. lunata的组织和具有相似特性的组织可能作为低频生物传感器和信号传输的组成部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Journal of Electromagnetics RF and Microwaves in Medicine and Biology ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

5.80

自引率

9.40%

发文量