18.3 Applications of Hydrogels in Bioelectronics
18.3.1 Coating of Hydrogel on the Neural Electrode
Neuron acts as an interface for the communication between the central nervous system
and bioelectronics devices. But chemical and the mechanical disparity between neuron
and bioelectronics devices cause aggravated inflammation response, an unreliable signal
collection due to nonconforming contact between the devices and the surface of skin or
tissue. The coating of a hydrogel on neural electrodes improves the functionality of
bioelectronics devices by providing intimate cellular integration and mechanical buffer
between hard electrodes and soft tissues. But as the thickness of a hydrogel coated on
neural electrodes increases, it may hamper the optimal performance of neural electrodes
due to lack of neurons near the electrode. The possible solution is to coat a conducting
polymer on the electrode to restore loss of functionality by an increase of the thickness of
the hydrogel on the electrode. To visualize the effect of hydrogel thickness on the re
cording quality of neural electrodes, ionically cross-linked alginate hydrogel (AH) having
different thicknesses were prepared on the neural electrode by dip coating. It was ob
served that as the AH thickness increased, the number of clearly detectable units gra
dually decreased, which could be due to a lack of neurons immediately around the
electrode sites. Furthermore, the conducting polymer PEDOT was also deposited on the
neural electrode along with AH. This improved the recording functionality of the AH-
coated electrodes. The biocompatible hydrogel was also applied for the differentiation of
human neural stem cells to enhance neuritogenesis via the electrical stimulation process.
Flexible PEDOT-based sodium alginate hydrogel-coated neural electrodes for the sensitive
neural recordings in guinea pig auditory were reported. PEDOT-CNT encapsulated fibrin
hydrogel-coated electrodes were designed to record somatosensory induced potentials into
a rat cortex through the deflection of multi-whisker. While agarose hydrogels doped with
surface-modified cellulose nanocrystals were fabricated to produce a diode [23]. A bionic
ear via 3D printing of a cell-seeded hydrogel matrix in the geometry of a human ear, with an
intertwined conducting polymer embedded with silver nanoparticles, was fabricated [24].
In-vitro culturing of cartilage tissue around an inductive coil antenna in the ear was per
formed, which enabled the readout of inductively coupled signals from cochlea-shaped
electrodes. Table 18.1 presents an overview of conductive hydrogels with their specific
features and applications.
18.3.2 Artificial Skin
The physiological environment has a huge impact on the performance of hydrogel
bioelectronic devices. Some hydrogel bioelectronic devices become unstable and fragile
on exposure to aqueous solutions or harsh physiological environments, significantly
impeding their desired applications. Biostable hydrogel bioelectronic devices that can
maintain their super mechanical and conductive properties, even when exposed to bio
fluids are highly desirable. By utilizing biocompatible cellulose and conducting reduced
graphene oxide (rGO), a biostable conducting hydrogel was prepared. A 2D planar cel
lulose crystal structure using the polydopamine-reduced graphene oxide was prepared.
This 2D planar cellulose crystal after physical and chemical cross-linking self-assembled
into a conducting hydrogel. This hydrogel showed high biostability and could withstand
long-term immersion in aqueous environments and implantation for over 30 days [45].
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Bioelectronics