Litcius/Paper detail

Highly Bionic Neurotransmitter-Communicated Neurons Following Integrate-and-Fire Dynamics

Shi Luo, Lin Shao, Daizong Ji, Yiheng Chen, Xuejun Wang, Yungen Wu, Derong Kong, Meng Guo, Dapeng Wei, Dapeng Wei, Yan Zhao, Yunqi Liu, Dacheng Wei, Dacheng Wei

2023Nano Letters17 citationsDOI

Abstract

In biological neural networks, chemical communication follows the reversible integrate-and-fire (I&F) dynamics model, enabling efficient, anti-interference signal transport. However, existing artificial neurons fail to follow the I&F model in chemical communication, causing irreversible potential accumulation and neural system dysfunction. Herein, we develop a supercapacitively gated artificial neuron that mimics the reversible I&F dynamics model. Upon upstream neurotransmitters, an electrochemical reaction occurs on a graphene nanowall (GNW) gate electrode of artificial neurons. Charging and discharging the supercapacitive GNWs mimic membrane potential accumulation and recovery, realizing highly efficient chemical communication upon use of acetylcholine down to 2 × 10 –10 M. By combining artificial chemical synapses with axon-hillock circuits, the output of neural spikes is realized. With the same neurotransmitter and I&F dynamics, the artificial neuron establishes chemical communication with other artificial neurons and living cells, holding promise as a basic unit to construct a neural network with compatibility to organisms for artificial intelligence and deep human–machine fusion.

Topics & Concepts

NeuroscienceNeurotransmitterDynamics (music)ChemistryBiophysicsBiologyNanotechnologyPhysicsMaterials scienceCentral nervous systemAcousticsPhotoreceptor and optogenetics researchNeural dynamics and brain functionNeuroscience and Neural Engineering