Covalent bonding of bioaffinity age

Covalent bonding of bioaffinity agents can also take place
of metal oxide nanobeads although require to be functionalized with organic (e.g. lauric acid) or inorganic (silicon oxide) derivatives (Frenzel, Lajn, & Grundmann, 2013). For
proteins the covalent bonding is achieved through glutaraldehyde or 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide
hydrochloride (EDC) coupling agent (Mishra, Srivastava,
Kumar, Biradar, & Rajesh, 2013). For covalent bonding
the outer shell of metal oxide beads are modified with silica
to impart functional groups to covalently link the bioaffinity
agent. Previous interest in immobilizing bioaffinity agents
(antibodies or bacteriophages) on paramagnetic beads was
as a concentration step referred to as immuno-magnetic separation (IMS) that used beads in the micron size range. However, IMS based on nanobeads have the advantage of higher
antibody loading by virtue of increased surface area although
stronger magnetic fields are required to facilitate bead capture (Shen et al., 2014). Hitherto, IMS has been used to
negate, or reduce the time required for the enrichment step
for pathogen screening. Here, the sample (homogenized
food or enrichment broth) is mixed with or flowed over,
modified-paramagnetic beads that captures the target which
can then be transferred to a diagnostic platform such as
real time-PCR (Fedio et al., 2011). Recent advances in the
application of paramagnetic beads is the integration of capture, concentration and detection in a single integrated unit.
For example, ELISA based assay where the target is
captured and reacts with a conjugate has been described for detection of h3/4 peanut allergen with a 0.2 mg/kg limit
of detection