15.4 Classes of Bioanalytical Sensors Based on MXenes
15.4.1 Bioelectronics
In recent years, two-dimensional MXenes have gained much attention owing to their
excellent electrical properties and good mechanical stability and hence they have been
utilized in biomedical applications. MXenes exhibit excellent qualities for fabricating
bioelectronics devices; however, self-restacking and agglomeration reduce their specific
surface area and stability, limiting their use in biomedical applications [33]. The most
effective technique to address such challenges is to transform 2D MXenes into 3D
MXenes. It has been found that converting accordion-like Ti3C2 MXene into urchin-like
sodium titanate (M-NTO) via oxidation and alkalization efficiently prevents MXene self-
stacking. However, the produced M-NTO tends to impair conductivity due to the wide
bandgap of sodium titanate (3.7 eV), and such problems could be efficiently managed by
inserting additional conductive materials into M-NTO. Because of their superior electrical
conductivity, ease of manufacture, and light weight, CPs are explored extensively among
various conductive materials and/or polymers [34]. PEDOT was an obvious candidate for
bioelectronics due to its superior stability, biocompatibility, and electrochemical catalytic
activity [34]. Incorporating conductive PEDOT with advanced nanomaterials could pro
duce synergistic effects, improve electrochemical sensitivity, and keep the morphologies
of the base substrates intact. Because of all of these factors, PEDOT is an excellent option
for incorporating M-NTO to enhance electrical conductivity. These materials (M-NTOP
EDOT) generate a huge surface area possessing quick transportation of electrons that
could be exploited to make biomedical gadgets [34]. For example, Xu et al. [35] described
label-free immunosensors based on gold nanoparticles (AuNPs) and M-NTO-PEDOT
to detect prostate-specific antigen (AuNPs/M-NTO-PEDOT) (PSA). The oxidation and
alkalization of HFetched Ti3C2 MXene nanosheets, followed by in situ oxidation to in
tegrate PEDOT with M-NTO, were used to make macroporous M-NTO in this study.
They also added AuNPs to the surface of M-NTO-PEDOT to increase the number of
binding sites for PSA antibodies. Hence, AuNPs/MNTO-PEDOT combination, which
possesses a huge surface area and good electrical conductivity, allowed the modified
electrode to load substantial amounts of PSA antibodies and transmit charge quickly. The
immunosensor’s advantages included increased electrochemical test sensitivity and
signal amplification. PSA was injected into human serum samples and detected within an
acceptable range of 96.13% to 107.1% by the immunosensor.
15.4.2 Enzyme Sensors
The creation of electrochemical biosensors requires direct electron transfer of electrons
directly among enzymes and electrodes. MXene has a variety of unique features, in
cluding a higher specific surface area and excellent electrical conductivity; hence, its
addition could be an effective means of facilitating direct electron transfer. It is worth
mentioning that, for the first time, Ti3C2 has been used in the construction of an elec
trochemical sensor towards hydrogen peroxide as a MXene [36]. Moreover, encapsulation
of enzyme hemoglobin, which directly correlates to the protein to keep it stable and active
has been done by using Ti3C2. Additionally, for mediator-free enzyme-based sensors,
Ti3C2 MXenes were suitable candidates for direct electron transfer of hemoglobin. Other
enzymes such as tyrosinase and acetylcholinesterase were also immobilized onto the
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Bioelectronics