Bidirectional flow of action potentials in axons drives activity dynamics in neuronal cultures

• Published in: Journal of neural engineering Vol. 18; no. 6; pp. 66045 - 66061
• Main Authors: Mateus, JC, Lopes, CDF, Aroso, M, Costa, AR, Gerós, A, Meneses, J, Faria, P, Neto, E, Lamghari, M, Sousa, MM, Aguiar, P
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 01.12.2021
• Subjects: Action Potentials - physiology; axonal electrophysiology; Axons - physiology; bidirectional axonal conduction; dorsal root ganglia; ectopic action potential; Ganglia, Spinal; hippocampal neurons; microelectrode array; microfluidics; Neurons; Synapses - physiology; microelectrode array; axonal electrophysiology; bidirectional axonal conduction; ectopic action potential; dorsal root ganglia; microfluidics; hippocampal neurons
• ISSN: 1741-2560; 1741-2552
• DOI: 10.1088/1741-2552/ac41db

. Recent technological advances are revealing the complex physiology of the axon and challenging long-standing assumptions. Namely, while most action potential (AP) initiation occurs at the axon initial segment in central nervous system neurons, initiation in distal parts of the axon has been reported to occur in both physiological and pathological conditions. The functional role of these ectopic APs, if exists, is still not clear, nor its impact on network activity dynamics. . Using an electrophysiology platform specifically designed for assessing axonal conduction we show here for the first time regular and effective bidirectional axonal conduction in hippocampal and dorsal root ganglia cultures. We investigate and characterize this bidirectional propagation both in physiological conditions and after distal axotomy. A significant fraction of APs are not coming from the canonical synapse-dendrite-soma signal flow, but instead from signals originating at the distal axon. Importantly, antidromic APs may carry information and can have a functional impact on the neuron, as they consistently depolarize the soma. Thus, plasticity or gene transduction mechanisms triggered by soma depolarization can also be affected by these antidromic APs. Conduction velocity is asymmetrical, with antidromic conduction being slower than orthodromic. Altogether these findings have important implications for the study of neuronal function , reshaping our understanding on how information flows in neuronal cultures.