conductivity and PSS for cation conductivity. This material has limitations due to its low
mechanical stability, so it is used together with additives such as acrylamide and poly(vinyl
alcohol), or in combination with higher mechanical resistant polymers, for example, Cuttaz
et al. synthesized a composite material of PEDOT: PSS and polyurethane (PU), for the
manufacture of flexible electrodes using laser micromachining, finding that dispersions of
10% to 15 % of PEDOT: PSS in PU achieve a balance between electrical and mechanical
properties, helping to increase the neuronal cells survival compared to pristine PU [18].
PPys become conductors when oxidized due to the delocalized electrons cloud throughout
the polymeric network; these materials also present biocompatibility, thermal stability, and
ease of synthesis, characteristics that allowed the manufacture of actuators based on PPy
films doped with BF4
-, which have potential application in the manufacture of artificial
muscles [19]. Finally, PANI is a low-cost conductive polymer due to its accessible synthesis,
which retains the characteristics of biocompatibility and chemical stability. The PANI
properties may be enhanced by combining it with secondary materials; for example, Cui
et al. developed a chitosan-PANI patch that tries to modulate the electrophysiology of
cardiac tissue and shows little inflammatory response in in-vivo assays [20].
Recent research works have sought the formulation of structures with multiple func
tions, which shows other characteristics in addition to charge transport, such as optically
active, catalytic properties, or are self-repairing. So, Uzuncar et al. presented a PANI: PSS
copolymer that was used for the fabrication of NH4
+ sensors and urea biosensors by
coupling with the enzyme urease, which showed high sensitivity and selectivity in
modeled urine samples [21].
2.2.2.1 Allotropes of Carbon
In addition to conductive polymers, allotropes of carbon, such as graphene and carbon
nanotubes (CNTs), are a good alternative for the development of bioelectronics detection
FIGURE 2.2
Molecular structures of the most used conductive polymers, PEDOT: PSS, PPy, and PANI.
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Bioelectronics