surface of a Ti3C2 MXene [37]. According to their findings, Ti3C2 MXene, which has good
metallic conductivity, huge surface area, and hydrophilic surface, is a viable choice for
constructing enzyme-based biosensors. Many studies have followed the technique of
mixing a Ti3C2 MXene and its functionalized materials, particularly different nanomater
ials, to increase the activity of enzyme-based biosensors based on Ti3C2 MXene. Wang, F.
et al., for example, modified TiO2 nanoparticles (NPs) on a Ti3C2 MXene to increase the
active surface area accessible for protein adsorption while maintaining enzymatic stability
and activity. When compared to a biosensor without TiO2 NPs, their constructed Hb-based
biosensor had a greater detection capability towards hydrogen peroxide.
Glucose sensing is critical since it is a predictor of diabetes. Because of their hydrophilic
nature, huge surface area, and unusual electrical conductivity, MXene nanosheets have
been used to make glucose sensors. Gu et al. produced a hybrid of Ti3C2Tx with graphene
nanocomposite to avoid stacking in 2D graphene [38]. The suggested nanomaterial
was deposited on the surface of a glassy carbon electrode for the construction of a glucose
sensor, followed by 10 mL glucose oxidase enzyme immobilization. In this method, the
proposed sensor has shown a controlled electrochemical process, which can be ascribed
by the potential scan rate and electron transfer rate, which is superior to previously re
ported 2D graphene sheet–based GOx biosensors [38].
It is well recognized that the use of GOx is influenced by the environment, which may
have an impact on its efficiency. As a result, Li et al. suggested that MXene nanosheets be
replaced with nickel-cobalt double-layer hydroxide, which has been useful towards
glucose determination because of its huge surface area and greater electrochemical ac
tivity. In addition, the two-layer hydroxide produces multiple catalytic sites and an ion
diffusion pathway. The suggested sensor featured a three-second glucose response time
and good selectivity [39].
The lower detection limit and sensitivity of the sensing platform could be created by
oxygen shortage in sweat, as well as the stability of sensors employing all-in-one working
electrodes produced using traditional methods, making detecting glucose and lactate in
sweat difficult. Using a foldable wearable sensor composed of MXene-Prussian blue
hybrid, Lei and colleagues developed a novel method for detecting hyperglycemia and
lactate in sweat perspiration. Carbon nanotubes (CNTs) were also used to improve the
sensor’s mechanical strength [40].
15.4.3 Non-enzymatic Sensors
Non-enzymatic biosensors are electrochemical devices that can be used to determine
biological chemicals and can catalyze spontaneous redox behavior of a variety of biolo
gical compounds by generating a significant voltage and electrical current. MXenes have
been used to construct the biosensor towards many small biomolecules as it favors
the electron transfer at the electrode interface in a quick manner, in this direction glucose
sensor has been performed by using a MXene/NiCo-LDH composite [39]. Due to the
many advantages of glucose oxidase-based sensors, much work has been done until
recently, and hydrogen peroxide (H2O2) is created during the catalytic activity of GOx, as
well as many other oxidases. Non-enzymatic PB/Ti3C2 hybrid nanocomposites may ea
sily evaluate hydrogen peroxide, according to some recent publications in this field [41].
Manufacturing an alternative non-enzymatic sensors using MXene with graphite
composite paste to form modified carbon paste electrodes that were responsive to
adrenaline and the detection limit was found to be 9.5 nM by chronoamperometry [42].
Differential pulse voltammetry (DPV) allowed for the precise assessment of adrenaline,
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