Amperometry is a quite sensitive el

Amperometry is a quite sensitive electrochemical technique in which the signal of interest is current
that is linearly dependent on the target concentration by applying a constant bias potential. Glucose is
oxidized at the working electrode composed of a noble metal formed by either the physical vapor
deposition or screen-printing and the biorecognition species such as GOx for glucose sensing [60]. An
amperometric biosensor comprises two or three electrodes. The former consists of a reference and a



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working electrode. Application of the two-electrode system to biosensors is limited, because at high
current flow the potential control becomes difficult as a result of sizable IR drop. Instead, the third
electrode is commonly introduced as an auxiliary counter electrode having a large surface area to make
most of current flows between the counter and the working electrodes, though voltage is still applied
between the working and the reference electrodes.
There are three modes of the glucose oxidation referred to as the first, the second and the third
generation glucose sensors depending on the electron transfer mechanisms. The nanostructured
metal-oxide based glucose sensor belong to the third generation. Figure 2(A) depicts the first
generation glucose sensor where oxygen is used as a mediator between the electrode and the GOx. The
oxygen is reduced to form hydrogen peroxide in the presence of glucose by flavin adenine dinucleotide
(FAD), a prosthetic group of GOx, and FADH redox couple. The reduction rate of the oxygen is
2
proportional to the glucose concentration that is quantified by either measuring the augmentation of
hydrogen peroxide or decrement of the oxygen concentration [5,61]. On the other hand, artificial
electron mediators (M), e.g., ferro/ferricyanide, hydroquinone, ferrocene, and various redox organic
dyes between the electrode and the GOx are employed in the second generation glucose sensor. These
mediators make the electron transfer rate between the electrode and the GOx faster and also give a way
of getting around for a case when limited oxygen pressure commonly observed from the first
generation glucose sensor [62,63]. Figure 2(B) represents the second generation glucose sensor, where
M
ox
and M
red
are the oxidized and reduced forms of mediator, respectively. The reduced form of flavin
group (FADH ) of GOx is reoxidized in presence of glucose by the reduction of M
2
ox
to form M
red
. The
output current signal generated, when further oxidation of M
red
occurs at the electrode surface, is
proportional to the glucose concentration [5,62,63].
Figure 2. (A) A schematic illustration of the first generation and (B) the second generation
amperometric glucose sensors (redrawn from reference [61]).