essential characteristic of this field of knowledge. Examples of this characteristic are new
biomaterials necessary for the operation of some electronic transducers [5]. Biomolecules
and ions constitute the communication mechanism within biological systems at the intra-
and inter-cellular level; this mechanism is the basis of bioelectronics; it opens possibilities
for lifesaving future therapeutic applications and integrates other types of applications,
including those envisioned by synthetic biology [6]. Thus, this discipline provides dif
ferent alternatives; some of them are already feasible while others have promising
technological development potential. Plastic bioelectronics stands out among these de
velopments: it combines polymers with the principles of soft organic electronics to pro
duce applications or materials that allow for adequate interfaces to achieve efficient
implementation within biological systems. [7].
Other relevant research includes bio-inspired adhesive architectures used in the health
sector on human body surfaces [8]; self-adhesive bioelectronics that can use hydrogels to
enhance the use of implants and wearable devices [9]; implantable bioelectronics, an
emerging and widely useful biomedical field whose applications could be used in diag
nostic tasks and therapeutic procedures [10]; and miniaturized devices, whose adequate
operation will require new power storage and supply technologies such as wireless transfer
to increase their useful life with compact designs [11]. Although bioelectronics has already
produced important advances, its challenges ahead are enormous. Therefore, supporting
science and technology is an essential activity, as well as developing mechanisms to pro
mote innovation in this sector.
7.2 Scientific and Technological Advances in Bioelectronics
Concerning living tissue, bioelectronics relies on a signal transduction mechanism that,
via different devices, creates an interface that allows for the measurement and regulation
of different biological functions to improve health and interventions against diseases [12].
Bioelectronic interfaces can be used on the skin or inside the organism [13]. An attractive
feature of organic electronic materials is their ability to conduct electronic and ionic
signals, which allows for adequate processing. On the other hand, organic electronic
polymers based on ad-hoc designs provide opportunities for specific answers regarding
the chemical and physical properties necessary for creating bioelectronic systems and
developing devices that combine mouldability, flexibility, and elasticity with stable and
biocompatible surface chemistry [14].
An interesting case is conjugated polymers, which can play the role of bridges for
multiple and potential applications combining biology and electronics thanks to the
versatile nature of their electronic and ionic conductivity profiles [15]. However, these
types of polymers are limited in terms of biodegradability, and for long-term use, very
few studies have focused on their biocompatibility, which has delayed their adoption and
the development of clinical applications [16]. Graphene is another suitable material for
bionic applications due to its physical and chemical properties and characteristics, ido
neous for constructing bioelectronic platforms [17,18]. For its part, ionic and electronic
(or mixed) transport offers valuable and feasible possibilities for organic bioelectronics,
and its uses can already be observed in applications such as electrolyte-based organic
electrochemical transistor activation [19,20]. These transistors can be used to detect ions,
hormones, and even pathogens, and they are idoneous for in-vivo applications capable of
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