other strains was obtained. This no-label approach was easy, rapid, and sensitive for
real-time bacteria detection in environmental samples [46]. Park et al. reported an im
munosensor for the detection of 2,4,6-Trinitrotoluene (TNT). Herein, they used single-
walled carbon nanotubes in a conducting channel of device, modified with an antibody
against TNT. This could detect TNT in a linear range of 0.5–5,000 ppb. The real water
sample analysis was done and they found that it showed great selectivity towards TNT in
presence of other nitroaromatic explosives [47]. In another work, Gong et al. prepared a
selective and highly sensitive mercury detection biosensor. This was a DNA-based sensor
fabricated over single-walled carbon nanotubes based on chemiresistive principle. The
device gave a linear range of 100–1,000 nM with LoD as 6.721 nM [48]. García-Aljaro
fabricated a chemiresitive immunosensor for the detection of two pathogens, E. coli and
Bacteriophage T7. Gold electrodes were placed parallelly and bridged with single-walled
carbon nanotubes. In further, antibodies corresponding to these pathogens were im
mobilized. There was a remarkable increase of resistance observed when the device
was tested with specified E. coli strain. No interference from other strains with LoD of
105 CFU/mL. Whereas, in the case of the virus, LoD of 103 PFU/mL was obtained with no
interference [49]. Liu et al. developed a biosensor device using photolithography and
PDMS. Graphene oxide sheets were coated over a Si/SiO2 substrate. This graphene
oxide was converted to a reduced form via a thermal approach. Rotavirus-specific anti
bodies were immobilized over this. The sensor was exposed to various rotavirus con
centration solutions and has an LoD of 102 PFU/mL [50]. Thus, the literature reveals that
printable biosensors have significant importance in environment monitoring and pollutant
detections.
22.3 Conclusion and Future Outlook
In recent times, substantial advances for the fabrication of novel analytical platforms with
flexible and printable biosensor electrodes have taken place. These have been re
volutionizing tools for the estimation of biological and environmental analytes. With the
integration of automation, microfluidics to prepare biosensors, point-of-care testing has
become feasible. Several advantages, such as instant, selective, and sensitive estimations
at the point of sample collection, multiplexed analyte detection, disposability as well as
re-usable features, ease of use, cost-effectiveness, smaller sample, and reagent volume,
have made them popular. The advances in these types of sensors have made analytical
detections laboratory-free. Various matrices and materials are being explored for fabri
cation. Since, bioreceptor molecules are sensitive and prone to lose activity, the matrices
play a significant role in the stability of the biosensors. The tremendous growth in the
future, in terms of preparations, materials, and applications is expected. With a special
focus on bridging the gap between academia fabrication, application, and industrial
production, in the future, printable biosensors can be made commercially viable. The
present chapter gives detailed information about the basic working principle of bio
sensors, types of biosensors based on bioreceptor, generations, and transducers. Brief
information on fabrication is also discussed. Recent advances and some remarkable
works reported for the application of flexible and printable biosensors in the detection of
biomarkers of ailments, pathogens for health monitoring, energy-harvesting fuel cells,
and environmental pollutant detections are also discussed. In conclusion, it can be
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