channel, which enabled electrophysiology recordings when measured as a function of
time. By exploiting a similar approach, Hess et al. fabricated graphene-FET arrays for
simultaneous multiplexed extracellular field potential recordings from electrogenic cells
from up to eight transistors [57]. Another important field of application of graphene
structures is intracellular recording, due to the fact that monitoring intracellular action
potentials is critical for in-depth electrophysiological and toxicological investigations. In
these regards, Dipalo et al. presented a microelectrode platform consisting of out-of-plane
grown three-dimensional fuzzy graphene (3DFG) that enables recording of intracellular
cardiac action potentials with high signal-to-noise ratio. The authors exploited the gen
eration of hot carriers by ultrafast pulsed laser for opto-porating the cell membrane and
creating an intimate contact between the 3DFG electrodes and the intracellular domain
[59], enabling the detection of the effects of drugs on the action potential shape of human-
derived cardiomyocytes (Figure 4.8). Fuzzy graphene has been also employed for
stimulation, recently. Specifically, Cohen-Karni and collaborators reported a hybrid na
nomaterial for remote, nongenetic, photothermal stimulation of 2D and 3D neural cellular
systems [60]. The authors combined one-dimensional (1D) nanowires (NWs) and 2D
graphene flakes grew out-of-plane for highly controlled photothermal stimulation at
subcellular precision without the need for genetic modification, with laser energies lower
FIGURE 4.8
(a) SEM images of the fuzzy graphene electrode. Scale bars, 5 µm (I), 1 µm (II), and 0.5 µm (III). (b) UV-vis
absorption spectrum of the 3DFG. (c) Real and imaginary parts of the dielectric constant of 3DFG. (d)
Photocurrent generated at the interface between 3DFG electrodes and PBS under excitation with ultrafast (pi
cosecond) pulsed laser at 1064 nm at different excitation powers. (e) Capacitive and faradaic current compo
nents of the photocurrent generated by laser excitation. Adapted with permission [ 59]. Copyright (2021)
American Association for the Advancement of Science. Distributed under a Creative Commons Attribution
License 4.0 (CC BY) https://creativecommons.org/licenses/by/4.0/.
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