1.4.2 Bioelectronics with Organic Semiconductor
Organic semiconductors have proven to be an excellent candidate for flexible and
stretchable bioelectronic applications, particularly in biosensors and biomedical devices,
due to a combination of their low-temperature solution-phase processability, good me
chanical deformability, and applicable charge transport properties. Organic bioelectronics
that is mechanically compliant, whether in contact with the skin or implanted into tissues,
can aid to lessen discomfort and other negative outcomes that can arise as a result of the
mechanical mismatch between the device and the body [34]. Furthermore, because many
organic semiconductors are self-healing and biodegradable, they are particularly well
suited for use in wearable and injectable bioelectronics applications, such as cardiac
monitoring. It will be necessary to consider many variables when developing the next
generation of organic bioelectronics, including the balance between mechanical deform
ability and device mobility, long-term stability under physiological conditions, stretching
and bending durability, among other things [35,36].
On the other hand, surface functionalization may also be utilized to produce
bio-recognition (Figure 1.5a, b) [37]. Mulla et al. [38] employed monomeric porcine
odorant-binding proteins (pOBPs) as ligands in a capacitive coupled p-type organic FET
FIGURE 1.4
(a) The illustration of coaxial p-type/intrinsic/n-type (p–i–n) Si-NWs architecture for photo-electrochemical
extracellular modulation of neuron membrane potential. Reproduced with permission [ 27]. Copyright (2018),
Springer Nature. (b) The tomographic representation of atomic probe of diffused gold on Si-NWs architecture’s
sidewalls. Reproduced with permission [ 31]. Copyright (2018), Springer Nature. (c) TEM/SEM images showing
the cross-section along with diffraction pattern of Si-NWs architecture. Reproduced with permission [ 32].
Copyright (2018), Springer Nature.
Introduction to Bioelectronics
9