Single layer graphene functionalized MEA for enhanced detection of neuronal network development

•Commercial multi-electrode-arrays (MEAs) well functionalized with single layer graphene (SLG) transferred via wet etching.•Spontaneous activity of neuronal networks on graphene was recorded from week 1 to week 4, up to complete network maturation.•Higher neuronal survival rate, higher adhered cell...

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Published in:Sensors and actuators. B, Chemical Chemical, 2018-12, Vol.277, p.224-233
Main Authors: El Merhie, Amira, Ito, Daisuke, Colombi, Ilaria, Keshavan, Sandeep, Mishra, Neeraj, Miseikis, Vaidotas, Diaspro, Alberto, Coletti, Camilla, Chiappalone, Michela, Dante, Silvia
Format: Article
Language:English
Subjects:
Burst detection
Bursting strength
Cross-correlation analysis
Electrodes
Etching
Grain boundaries
Graphene
Morphology
Multi-electrode-arrays
Neural networks
Neuronal networks
Recording
Sensors
Spike detection
Substrates
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Summary:•Commercial multi-electrode-arrays (MEAs) well functionalized with single layer graphene (SLG) transferred via wet etching.•Spontaneous activity of neuronal networks on graphene was recorded from week 1 to week 4, up to complete network maturation.•Higher neuronal survival rate, higher adhered cell number and enhanced firing activity were detected on SLG versus control.•Neuronal network activity was detected earlier on graphene and a more synchronous behavior of the network was recorded.•Graphene functionalized MEAs showed an improved detection capability, possibly due to a better neuron/substrate coupling. The exploitation of graphene for neuro-interfacing applications requires a complete, yet missing, understanding of neuron-graphene interaction. Here, we have explored the interplay between the carbon based interface and neuronal networks during the complete developmental phase at whole network scale. To this purpose, we have, first, successfully transferred large grains single layer graphene (LG-SLG) via wet etching onto commercial planar 60 electrode devices; then, we have compared to control the neuronal growth on the functionalized devices, recording the spontaneous activity up to completion of network maturation, i.e., from 7 to 25 days-in-vitro. The immunohistochemistry investigation demonstrated a comparable morphology of the neuronal network on SLG and control substrates but with a higher number of neurons on SLG. The most striking results of the electrophysiological investigation were the observation of spikes and bursts activity at an earlier developmental phase and of strongly synchronized neuronal networks on SLG-MEA versus control, suggesting an improved neuron/electrode coupling. These observations agree with our previous study of single neuron synaptogenesis by patch clamp, where earlier synaptogenesis on SLG compared to the control was detected. The results have been corroborated by the firing and bursting analysis showing higher and statistically significant values on SLG-MEA.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2018.08.142