This is the case of π-conjugated molecules and oligomers, which are being utilized to
trigger electron injection or for photostimulation. In this section, we will focus on three
main classes of photosensitive bioelectronic molecules: conjugated oligomers, organic
dyes/pigments, and photoswitches.
4.4.1 Conjugated Oligomers
Conjugated oligoelectrolytes (COEs) consist of a π-delocalized backbone and ionic pen
dant groups, have been demonstrated to modify the abiotic/biotic interface via efficient
insertion in the plasma membrane (Figure 4.5a,b) [39]. The COE chromophore mainly
undergoes radiative decay via emission or nonradiative decay via heat generation or
energy/electron transfer to acceptors (such as dyes and/or oxygen) upon light excitation.
This molecular unit is ultimately responsible for some important bioelectronic properties
of COEs, i.e. the photoinduced production of reactive oxygen species, [40] increase of
the local temperature, and the facilitation of extracellular electron transport to abiotic
electrode surface via direct electron transfer and/or meditated electron transfer. In ad
dition, emission enables facile tracking of the chromophore via simple fluorescence mi
croscopies. On the other hand, the ionic side chains confer water solubility and enable
specific interaction with targets via electrostatic interactions, leading to the disruption or
stabilization of the plasma membrane, depending on the COE molecular size. For in
stance, disruption can occur via membrane thinning, as the lipid phosphate head groups
are drawn toward the center of the bilayer. For all these reasons, COE have been em
ployed for a plethora of applications, including in microbial fuel cells, as light-driven
antibacterial agent, as biosensors and in photodynamic and photothermal therapy [39,41].
4.4.2 Organic Dyes and Pigments
Historically, dyes and pigments have been used as electronic materials. One of the most
famous examples is perhaps Tang’s photovoltaic cell, consisting of a bilayer of copper
FIGURE 4.5
(a) Schematic of the COE structure with a π-conjugated internal region (rectangle) and polar pendant group
terminals (circle) intercalating into a lipid bilayer. b) Typical COE chemical structure.
62
Bioelectronics