contained a microchannel, reservoir, and inlet hole. The transparent glass slide was used
to attach the channel. The AgNPs could enhance the storage capacity, electrical con
ductivity, and electrocatalytic properties, while chitosan may provide hydrophilicity and
functional group for hydrogen binding with amine and hydroxyl group. The AgNPs/
Chitosan/PGE electrode showed high storage capacity of 367.16 mF/cm2 and a current
density of 1 mA/cm2 with high cyclic stability of more than 1,500 charge-discharge cy
cles. As for electrochemical sensors in H2O2 detection, the microfluidic AgNPs/Chitosan/
PGE had linear detection of 1-10M and LOD of 0.52M.
PtNPs have also been utilized for the development of LOC devices. The microfluidic
LOC for vitamin B detection was developed based on chemiluminescence (CL) of luminol
[16]. In their work, PtNPs acted as a catalyst to enhance the luminol CL signal caused by
the oxidation of AgNO3. With the presence of vitamin B, the CL of luminol signal in
tensity increased. The microfluidic LOC was fabricated using soft lithography of the
PDMS with four sample inlets and one sample outlet. The microfluidic LOC for vitamin
B detection has the linear detection in the range of 1.0 × 10−7 to 4.0 × 10−5 mol/L and LOD
of 4.8 × 10−9 mol/L. In addition, an interesting LOC device which consists of two plat
forms for pesticide atrazine (Atz) detection and degradation was developed by Sánchez
et al. [17]. The enzymatic activity of the boron-doped diamond (BDD) electrodes modified
with PtNPs and horseradish peroxidase (HRP) in Atz detection was evaluated using the
chronoamperometry technique. The PtNPs had improved the catalytic activity of the HRP
enzymatic reaction. The magnetic beads were integrated into the LOC device to pre-
concentrate and direct the sample into the microchannel. Meanwhile, the degradation of
the Atz pesticide was conducted using anodic electrochemical oxidation where the un
modified BDD electrode acted as the anode, carbon electrode as the cathode, and Ag/
AgCl as the reference electrode. In the anodic electrochemical oxidation, the oxidation
of water produced hydroxyls radicals (HO·) on the BDD anode surface. The produced
HO· radicals subsequently reacted with the Atz pesticide and caused degradation.
The Atz LOC chip showed a linear response in the range of 0.9–4.5 nM and a very low
LOD of 3.5 pM.
5.3.2 Metal Oxide Nanomaterials in Lab on Chip
Metal oxide (MO) nanomaterials have been explored for modification of sensor platforms
in LOC devices. The MO nanomaterials exhibit high surface area, excellent electron-
transfer kinetics, inexpensive to produce, and have effective catalytic properties, making
them an excellent choice for signal enhancing in optical, electrochemical, and electrical-
based LOC devices. Metal oxides such as ZnO, CuO, Fe3O4, SnO2, MnO2, ZrO2, TiO2, and
MgO have been applied as sensor modifiers of the LOC devices for various applications.
Table 5.3 lists the metal oxide nanomaterials applied in LOC devices for various appli
cations and detection techniques. Among all MO nanomaterials, ZnO nanomaterial is of
interest for a range of sensors such as gas, biological, and electrochemical sensors. ZnO
has excellent electrical, catalytic, and optical properties. ZnO is classified as a semi
conductor in groups II–VI, which exhibits a direct bandgap ~3.37 eV. In principle, one-
dimensional (1-D) ZnO nanostructures (nanorods, nanowires, and nanotubes) are more
favorable because the structures may facilitate efficient carrier transport. This happens
because of 1-D ZnO nanomaterial has decreased grain boundaries, surface defects, dis
orders, and discontinuous interface [19].
Most commonly, ZnO nanorods (ZnO NR) have been extensively studied for gas sensor
applications. The reason is that ZnO NR is an excellent chemiresistive material. The
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