addition to this surface chemical modification; “thiol modification” on the Au electrode
surface for the formation of a poled β-PVDF film is an additional advantage to improve
the carrier injection efficiency at the metal/organic interface of the electrode devices [36].
However, thiol modified Au electrodes presented polarization of the PVDF film-based
pressure sensors performs better.
23.4 Functions and Devices in Recent Bioelectronic Application
As an advancement towards flexible and wearable bioelectronics, they also demonstrated
that molecular doping of PTh with oligoethylene glycol side chains increases its degree of
π-stacking, strongly modulates its electrical conductivity to >52 S/cm, the toughness from
0.5 to 5.1 MJ/m3, and elastic modulus from 8 to >200 MPa [37]. A new-generation
wearable, flexible, therapeutic photoelectronic dual-responsive wound dressing has been
designed from selenoviologen-appendant polythiophene containing polyacrylamide hy
drogels. This sandwich device ensures sustained in situ reactive oxygen species (ROS)
generation in a physiological environment via six seconds short-time light irradiation
with or without wireless-controlled electrification. The derivative harnessing the high
conductivity and strong light absorption properties of PTh along with efficient ROS
generation properties of selenoviologens was immersed in polyacrylamide hydrogels.
When put directly over the bacterially infected wound, it starts generating ROS outflow
under visible light and/or electrical stimulation thereby limiting the healing time of in
fected full-thickness wounds up to 7 days. Interestingly, this is a BlueTooth-enabled, cell
phone–controlled, free-radical generation system. The green color, upon turning the cell
phone on, indicated a ROS generation, which turned to yellow upon switching off. This
electronic switching on and off was repeatable and had optical memory too [38].
Most of the research is limited to in vitro applications of PANi-based electrodes. It is
widely being used for in-vivo applications ranging from tumor imaging and treatment,
photothermal treatment, sensors, tissue regeneration, and drug delivery. It is used in
tumor therapy as the image-guided phototherapeutic agent. Further, limited negligible
toxicity was observed in vivo implantation. In another interesting work, researchers
tagged iron-copper co-doped PANi nanoparticle as a metal dopant platform with PANi
nanoparticles and utilized the ability of Cu to undergo redox reaction with glutathione of
tumor microenvironment. This was further verified with tumor photoacoustic imaging
and in vivo photothermal therapy [39]. The bacterial microenvironment hampers the PTT
and it leads to a decreased theranostic effect of nanoparticles. Yan et al. reported the
PANi and glycol chitosan functionalized core-shell nanostructures with persistent lu
minescent imaging and capability of pH switchable platform for in vivo mice photo
thermal therapy [40]. Another widely explored in vivo application is based on the utility
of PANi to sense different biomolecules. Glucose biosensors based on PANi with limited
interference was fabricated with double-sided flexible electrode for continuous mon
itoring in a rat model after 24 hours’ post-implantation [41]. Nanoporous PANi mem
brane along with polymerized tannic acid-coated carbon fiber electrode is being used
for DA sensing in rats at medial forebrain bundle in the brain. Here, the antifouling
capability was observed over the membrane as bovine serum albumin (BSA) protein
adsorption was found to be very low and it was then able to sense DA oxidized product
on its surface with high sensitivity [42].
384
Bioelectronics