Litcius/Paper detail

Proteinoid Microspheres as Protoneural Networks

Panagiotis Mougkogiannis, Andrew Adamatzky

2023ACS Omega16 citationsDOIOpen Access PDF

Abstract

Proteinoids, also known as thermal proteins, possess a fascinating ability to generate microspheres that exhibit electrical spikes resembling the action potentials of neurons. These spiking microspheres, referred to as protoneurons, hold the potential to assemble into proto-nanobrains. In our study, we investigate the feasibility of utilizing a promising electrochemical technique called differential pulse voltammetry (DPV) to interface with proteinoid nanobrains. We evaluate DPV's suitability by examining critical parameters such as selectivity, sensitivity, and linearity of the electrochemical responses. The research systematically explores the influence of various operational factors, including pulse width, pulse amplitude, scan rate, and scan time. Encouragingly, our findings indicate that DPV exhibits significant potential as an efficient electrochemical interface for proteinoid nanobrains. This technology opens up new avenues for developing artificial neural networks with broad applications across diverse fields of research.

Topics & Concepts

Differential pulse voltammetryMicrosphereNanotechnologyElectrochemistryCyclic voltammetryLinearityMaterials sciencePulse (music)ChemistryBiological systemComputer scienceElectrodeElectronic engineeringChemical engineeringEngineeringPhysical chemistryBiologyTelecommunicationsDetectorNeuroscience and Neural EngineeringElectrochemical Analysis and ApplicationsPhotoreceptor and optogenetics research