antigens, neurotransmitters, enzyme substrates, DNA fragments, and drug metabolites.
These polymeric biosensors can be examined by electrochemical, optical, or piezo
gravimetric detectors with very high sensitivities, and low detection limits.
18.2.1 Conducting Polymer–Based Hydrogels
Conducting hydrogels are often synthesized by mixing insulating polymer matrices
(providing structural support and water holding properties) with conducting polymer or
filler material (providing electrical conductivity). Metallic nanoparticles, carbon nano
tubes, graphene, and their derivatives have been extensively employed to prepare con
ducting hydrogel due to their electrical and mechanical properties. However, the rigid
and fragile nature of conducting polymers hampers the long-time stability of hydrogels
and restrains the wider applications in emerging flexible electronic devices. Synthesis of
conducting hydrogel along with excellent biocompatibility is highly required for the
development of bioelectronics and energy devices.
Several electrically conductive polymers including PPy, PANI, PEDOT, and PTH-based
hydrogels with their synthetic flexibility have gained widespread interest in bioelec
tronics applications. Conducting polymer-based hydrogels has the additional benefit of
electrical conductivity over conventional hydrogels. Conducting polymers such as PPy
have also been widely employed along with dopants for conductive hydrogels designing
as they provide conductive pathways for bio-electrocatalysis of enzymes. The first con
ducting hydrogel was synthesized by Gilmore and group by direct electropolymerization
of PPy on pre-prepared polyacrylamide hydrogel in the cylindrical gel cell [2], while the
Wallace group has prepared a range of conducting polymer-based electroactive hydrogel
composites bearing excellent rehydration levels up to 80–95% [3]. The composites based
on the growth of conducting film of PPy or PANI throughout hydrogel were investigated.
Excellent water-retaining capacity and the stimuli-responsive electrochemical release of
larger incorporated counterions provide an open porous structure of the resultant hy
drogel materials. The hydrogel composites, with retained properties of hydrogel, present
newer electrochemical applications of these materials. An enzyme-based biosensor was
fabricated by an electrosynthetic approach of conducting PPy with alginate as co-dopant
of laccase (an oxydoreductase enzyme) and 2,2′-and-bis(3-ethyl benzothiazoline-6-
sulfonic acid) (a redox mediator) [4]. The catalytic effect of PPy film as a function of
several cycles at various ratios of alginate doped laccase was examined. The catalytic
effect was found to enhance the number of cycles from 0 to 10, and further decreased as
the number of cycles increased.
PEDOT is a widely used conducting polymer in the field of bioelectronics and has en
abled improvements in the electrical conductivity of metallic electrodes and provided
functional versatility of biomolecules. Doping of PEDOT with several counterions was
reported. A biocompatible polyurethane hybrid composite (PUHC) hydrogel formed by
dispersion of polyurethane with PEDOT:PSS and liquid crystalline graphene oxide shows
high conductivity, stretchability, and good mechanical performance. Certain organogels of
PEDOT:PSS with polyacrylamide (PAAm) allowed electronic transport within organogel.
Conducting polymers incorporated hybrid hydrogels are promising materials for bioactive
electrode coatings. A blending of conducting polymers into hydrogels helped in improving
the electrical, mechanical, and biological properties of inherent hydrogels, e.g., flexible
conducting polymer PEDOT-based sodium alginate hydrogel coated neural electrodes.
PEDOT: PSS was added to CS/PVA scaffolds causing a significant enhancement in
the mechanical and electrical properties for cardiovascular engineering. Chitosan (CS), a
Conductive Hydrogels for Bioelectronics
293