Frontiers in Neuroscience (Jan 2022)

Bidirectional Modulation of Neuronal Cells Electrical and Mechanical Properties Through Pristine and Functionalized Graphene Substrates

  • Francesca Zummo,
  • Pietro Esposito,
  • Huilei Hou,
  • Cecilia Wetzl,
  • Gemma Rius,
  • Raphaela Tkatchenko,
  • Anton Guimera,
  • Anton Guimera,
  • Philippe Godignon,
  • Philippe Godignon,
  • Maurizio Prato,
  • Maurizio Prato,
  • Maurizio Prato,
  • Elisabet Prats-Alfonso,
  • Elisabet Prats-Alfonso,
  • Alejandro Criado,
  • Alejandro Criado,
  • Denis Scaini,
  • Denis Scaini

DOI
https://doi.org/10.3389/fnins.2021.811348
Journal volume & issue
Vol. 15

Abstract

Read online

In recent years, the quest for surface modifications to promote neuronal cell interfacing and modulation has risen. This course is justified by the requirements of emerging technological and medical approaches attempting to effectively interact with central nervous system cells, as in the case of brain-machine interfaces or neuroprosthetic. In that regard, the remarkable cytocompatibility and ease of chemical functionalization characterizing surface-immobilized graphene-based nanomaterials (GBNs) make them increasingly appealing for these purposes. Here, we compared the (morpho)mechanical and functional adaptation of rat primary hippocampal neurons when interfaced with surfaces covered with pristine single-layer graphene (pSLG) and phenylacetic acid-functionalized single-layer graphene (fSLG). Our results confirmed the intrinsic ability of glass-supported single-layer graphene to boost neuronal activity highlighting, conversely, the downturn inducible by the surface insertion of phenylacetic acid moieties. fSLG-interfaced neurons showed a significant reduction in spontaneous postsynaptic currents (PSCs), coupled to reduced cell stiffness and altered focal adhesion organization compared to control samples. Overall, we have here demonstrated that graphene substrates, both pristine and functionalized, could be alternatively used to intrinsically promote or depress neuronal activity in primary hippocampal cultures.

Keywords