amplifies the current signals into a readable digital display in the readout device [3].
Figure 22.1 gives a schematic representation of the workings of the biosensor device.
22.1.1 Categories of Biosensors
22.1.1.1 Classification Based on Bioreceptor
As shown in Figure 22.1, mainly five kinds of bioreceptors are used for the fabrication of
biosensors. Based on these, there are different types:
1. Enzyme-based biosensor: In these, an enzyme is used as a bioreceptor over the
matrix. This can detect a specific analyte substrate that can compatibly bind with
the enzyme. It has a lock and key model. Enzymes are target analyte-specific.
Enzymes that can recognize the analytes are effective biocatalysts. For instance,
glucose oxidase for glucose, urease for urea, peroxidases for peroxide, etc. The
analyte detection depends upon the attributes like enzyme changing the analyte to
a detectable form, pH, temperature, substrate concentration, enzyme concentra
tion, etc. Although enzyme-based biosensors are highly selective and specific, there
are certain limitations related to stability and adaptability [4].
2. Antibody/immunosensor: These biosensors are used for pathogen and infection
analysis. An antibody (Immunoglobin-Ig) is a bioreceptor and is used for the de
tection of diseases and biomarkers like cancer, cardiovascular diseases, hepatitis, etc.
Ig is a target antigen-specific and is immobilized on the matrix. Ig binds with the
antigen to form an antigen-antibody complex, which causes electron shuttling [5].
3. DNA-based biosensor: Herein, complementary DNA strands, usually single strands,
are used as the bioreceptors on the matrix. The target analyte DNA is denatured
chemically and mixed with the electrolyte. The matching sequence identifies this
strand and forms double-stranded DNA bond causing electron transfer [6].
4. Cell-based biosensors: Herein, live microorganisms cells like bacteria and fungi
are used as bioreceptors over the matrix. These measures intracellular and ex
tracellular parameters. The major limitation is stability and contamination [7].
5. Biomimetric biosensor: Here, synthetic DNA sequences, called aptamers, are
used as bioreceptors over the matrix, which mimic the natural DNA sequence.
These are used for the detection of proteins, amino acids, etc. These are slightly
advantageous as they can be manipulated as needed [8].
FIGURE 22.1
Schematic representation of biosensor components and working principle.
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Bioelectronics