Electrolyte-gated organic synapse transistor interfaced with neurons

Adrica Kyndiah; David Guerin; Dominique Vuillaume; Fabio Biscarini; Marianna Barbalinardo; Mauro Murgia; Michele di Lauro; Silvia Tortorella; Simon Desbief; Stefano Casalini

arxiv: 1608.01191 · v1 · pith:5Z6Y62BYnew · submitted 2016-08-03 · ❄️ cond-mat.mes-hall · physics.bio-ph· q-bio.NC

Electrolyte-gated organic synapse transistor interfaced with neurons

Simon Desbief , Michele di Lauro , Stefano Casalini , David Guerin , Silvia Tortorella , Marianna Barbalinardo , Adrica Kyndiah , Mauro Murgia

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Tobias Cramer Fabio Biscarini Dominique Vuillaume

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classification ❄️ cond-mat.mes-hall physics.bio-phq-bio.NC

keywords neuronsegosplasticityshort-termcellselectrolyte-gatedinterfacedorganic

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We demonstrate an electrolyte-gated hybrid nanoparticle/organic synapstor (synapse-transistor, termed EGOS) that exhibits short-term plasticity as biological synapses. The response of EGOS makes it suitable to be interfaced with neurons: short-term plasticity is observed at spike voltage as low as 50 mV (in a par with the amplitude of action potential in neurons) and with a typical response time in the range of tens milliseconds. Human neuroblastoma stem cells are adhered and differentiated into neurons on top of EGOS. We observe that the presence of the cells does not alter short-term plasticity of the device.

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Electrolyte-gated organic synapse transistor interfaced with neurons

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