Food Biochemistry and Food Processing (2 edition)

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BLBS102-c45 BLBS102-Simpson March 21, 2012 14:38 Trim: 276mm X 219mm Printer Name: Yet to Come


45 Biosensors for Sensitive Detection of Agricultural Contaminants, Pathogens and Food-Borne Toxins 867

Table 45.5.The Ideal Characteristics and Properties of
an Electron Mediator


  1. Exhibits reversible kinetics.

  2. Reacts readily with the reduced form of an enzyme.

  3. Has a low oxidation potential and is mediator activity is
    pH independent.

  4. Is stable in both redox forms.

  5. Easily retained at the surface of an electrode.

  6. Unreactive towards oxygen.

  7. Chemically unreactive with the immobilised biological
    material.


Table 45.5 illustrates the characteristics that are favourable in
choosing a specific mediator (Cassidy et al. 1998).
Mediators are usually low molecular redox couples that shut-
tle the electrons from the enzyme’s active site to the surface
of the transducer. Equation 2 illustrates the reaction of the me-
diator and the subsequent generation of an electron resulting
electrochemical cycling.

H 2 O 2 +2H++2e−→2H 2 O(1)
Mediatorred→Mediatorox+e− (2)

Equations 3, 4, 5 and 6 illustrate a peroxidase-mediated reac-
tion on a biosensor surface. Equation 3 shows the resting state
peroxidase (in its reduced form) reacting with hydrogen perox-
ide and two hydrogen ions to form an intermediary oxidised-
peroxidase compound and two water molecules. Equation 4
shows the reaction of the intermediary oxidised-peroxidase com-
pound with the reduced form of a mediator to produce the resting
reduced-state peroxidase and an oxidised mediator. Equation 5
shows the oxidised mediator reacting with two electrons, thus,
reverting to the reduced form of the mediator. It is these electrons
that the transducer detects and converts into an electrical signal.

The final Equation 6 shows the overall reaction, whereby one
hydrogen peroxide molecule in the presence of two electrons and
two hydrogen ions is converted to two water molecules (Ryan
et al. 2006).

H 2 O 2 +2H++POred→POox+2H 2 O(3)
POox+Mediatorred→POred+Mediatorox (4)
Mediatorox+2e−→Mediatorred (5)
H 2 O 2 +2e−+2H+→2H 2 O(6)

It is often possible to use a multi-enzyme electrochemical
biosensor system to detect the presence and determine the con-
centration of a particular compound in a matrix of interest. This
method employs two or more enzymes that are in proximity with
each other and in contact with a mediator or directly in contact
with the transducer. As illustrated in Figure 45.8, enzyme 1 (glu-
cose oxidase (Gox)) generates hydrogen peroxide (H 2 O 2 )asa
by-product through the catalysis of glucose by Gox. The H 2 O 2
generated is catalysed by a peroxidase enzyme and the redox
cycling of the mediator. The cycling of the peroxidase enzyme
in the presence of H 2 O 2 generates electrons that are detected
by the transducer. This in turn enables the concentration of the
target analyte to be determined, thereby providing quantitative
determination.
There are several well-characterised electrochemical biosen-
sor devices that have been applied in the fruit and vegetable
industry for the detection of a number of structurally di-
verse compounds, including pesticides, herbicides, insecticides,
organophosphates, organochlorines and carbamates. With ref-
erence to the detection of pesticide residues, there are many
available options that can be implemented by the end user. More
specifically, enzymes that are directly affected by the presence
of a pesticide can be incorporated into a biosensor-based plat-
form permitting detection (Amine et al. 2006). As an example,
acetylcholinesterase (AChE) presents in muscles, red blood cells

Substrate

Gox Enzyme

H 2 O 2

Product

e-

R

R'

Transducer

Electrical signal

Figure 45.8.A representation of a sensor with two enzymes operating together. The first enzyme catalyses the substrate of interest and, as a
by-product, H 2 O 2 is generated. This is then catalysed by a peroxidase enzyme. The redox activity of the peroxidase enzyme is detected by
the transducer. Gox is glucose oxidase; H 2 O 2 is hydrogen peroxide; R and R′represent the oxidised and reduced forms, respectively, of an
electron mediator and e−is an electron.
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