Another in-vivo skin-mounted skeletal muscle tissue stimulation was shown by ionic
hydrogel system localized in-vitro cultured cells electrical stimulation. Yuk et al. reported
ionically conductive tough hydrogel for constructing electronic devices under large de
formation using soft, flexible, and stretchable conductive material [12]. For the sake of
brevity, details of such applications are presented in Table 18.1.
18.3.3 Flexible and Implantable Bioelectronics
Regular and continued monitoring of vital signs of the body such as body temperature,
blood pressure, and estimation of analytes in body fluids is necessary for maintaining a
healthy life. Currently, electrocardiography (ECG), electroencephalography (EEG), and
electromyography (EMG) are used to monitor these vital signs of the body. The acquisition
of their signals is typically achieved by metal electrodes which can cause skin damage/
irritation. Moreover, these electrodes are rigid and cannot withstand stretching and
bending. Therefore, soft and flexible epidermal patches are highly desirable. Conductive
hydrogels are tissue-friendly and their tunable electrical properties, flexibility, and bio
compatibility make them useful for epidermal patches. A conducting hydrogel was pre
pared by mixing polyvinyl alcohol (PVA), borax, and PEDOT:PSS screen-printing paste to
use in epidermal patches. Prepared hydrogels exhibited high skin adhesion, high plastic
stretchability, moderate conductivity, and self-healing properties. The hydrogel was ap
plied for the recording of ECG and EMG signals, which showed high-quality recording.
An ion-conducting (Ch-CMC-PDA) hydrogel using chitosan (Ch), cellulose (CMC), and
dopamine (DA) [29]. Ch-CMC-PDA the hydrogel was applied for ECG signal detection; the
result showed that the ECG pattern obtained using Ch-CMC-PDA was identical to com
mercial gel Cardijelly.
PEDOT:PSS-PAAm organogels possess a better transport of electrical signals and was
highly stretchable. PEDOT:PSS added to CS/PVA scaffolds was introduced for the sake
of better mechanical and electrical properties for cardiovascular engineering. The con
ductive PDA–pGO–PAM hydrogels with high stretchability, self-healing ability, and self-
adhesiveness potential pave the way as cell stimulators and implantable bioelectronics for
the human body (Figure 18.2) [18]. Soft and conductive r(GO/PAAm) hydrogels were
also found to be useful material for skeletal muscle tissue engineering scaffolds [19]. The
incorporation of small amounts of CNTs into gelatin-chitosan-based hydrogel supports
cardiomyocyte function and helped to attain the electrical conductivity of the beating rate
of the hearts [22]. Tissue-engineered scaffolds with the combined properties of CNTs
improved the cardiovascular defect repairs. The conductive biopolymer-based hydrogel
can behave as an artificial nerve in a 3D-printed robotic hand. This may allow tunable
electrical signals to pass and full recovery with robotic hand movements. This natural
highly elastic (up to 900 kPa) ionic conductive hydrogel is visualized to contribute to
artificial flexible electronics. The conducting 3D-printable scaffolds showed good cell
adhesion, are biodegradable, and have cytocompatible properties to be used in tissue
engineering. C2C12 myoblasts grown on the hybrid GelMA-vertically aligned CNT hy
drogels yielded functional myofibers [46], after applying electrical stimulation in the
direction of the aligned CNTs, than cells that were cultured on the GelMA hydrogels with
randomly distributed and horizontally aligned CNTs.
The development and application of printed MEA arrays on soft substrates including
PDMS and hydrogels were conducted [47]. To this end, a straightforward printing pro
cess was introduced that exploits controlled wetting properties of carbon and polyimide
inks on PDMS, curtailing major problems that are often faced in printing structures. The
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Bioelectronics