and electrical characteristics that are superior to those of pure Pt NPs. This composite
may be used to print high-resolution 3D structures. Thus, the fabrication of future 3D
wearable bioelectronics with improved mechanical and electrical characteristics will be
possible in the future. Because of their enormous surface area, Pt NPs-decorated
Si composites have the potential to provide cathodal charge storage capacities of
B50 mCcm2, which are comparable to those of strongly doped organic electrode coatings.
Aside from providing superior catalytic performance over hydrogen peroxide, Pt NPs
significantly improve the current density and detection sensitivity of graphene-based
glutamate and glucose sensors [40].
In another study, to monitor the intracellular action potentials in excitable cells such as
neurons and cardiomyocytes, Au-based nano-pillar with a mushroom-shaped have also
been demonstrated to be capable of recording subthreshold synaptic activity and action
potentials in vitro with minimal invasiveness for days at a time, which is 50 times longer
than the typical patch-clamp techniques [41]. Researchers discovered that mushroom-
shaped Au micro-electrodes significantly improved membrane engulfment, which is
advantageous for their application because it results in the formation of high resistance
seals between the interfaced cell and the electrodes [42].
1.4.4 Bioelectronics with Nanocarbons
Nanocarbons like graphene and carbon nanotubes (CNTs) are valued in bioelectronics due
to their exceptional chemical stability, biocompatibility, recyclability, great mechanical
flexibility, a huge surface area, and a broad electro-mechanical range. Nanocarbons are
used in the fabrication of fiber-like probes for biomedical applications. Energy storage and
electrochemical sensing are examples of electrochemical technologies using these carbon
materials. In addition, carbon microelectrodes with a conductive coating have been used for
high-resolution measurements. With an increase in synaptic activity as well as in vesicles,
oxidation of carbon fiber in a cell or near a cell can also take place [28,43].
1.4.5 Bioelectronics with Organic Conductors
Making conducting materials that are both very flexible and mechanically robust is one of
the most challenging difficulties faced by researchers working on bioelectronics in the past
few decades. In comparison to the majority of inorganic conducting materials currently on
the market, organic conducting materials, such as conjugated polymers and hydrogels,
have the potential to be more biocompatible and easier to manufacture [44,45]. The con
ductive polymers have been discovered for use in flexible electronics, and only a few have
been used for bioelectronics applications. Current research is mostly focused on three
materials, namely poly(3,4-ethylenedioxythiophene)poly(styrene sulfonate) (PEDOT-PSS),
polypyrrole (PPy), and polyaniline (PANI) in particular [46].
The development of synthetic approaches to increase the purity of PEDOT-PSS is im
portant due to the risk that additives may impair the material homogeneity and introduce
the possibility of cytotoxicity. Because of the collapse of the fibrillary structure, which
decreases the conductivity of pure PEDOT-PSS hydrogels when synthesized under normal
conditions, it is difficult to obtain a consistent result in the laboratory (Figure 1.6a) [46].
Purified PEDOT-PSS may be produced using a process developed by Luet al. [46] that
maintains the desired features like the material’s stability, flexibility, and conductivity.
Adding DMSO to aqueous PEDOT-PSS, they were able to form interconnected and pure
PEDOT-PSS nano-fibrils (Figure 1.6b). At the end of the process, a dry phase-separated
Introduction to Bioelectronics
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