surface of SPIO NPs. The PEG coating on SPIO provides an additional advantage to
extend the blood half-life time of SPIO NPs. The tracer exhibited superior colloidal
stability and persistent intravascular MPI signal for the generation of blood pool
tracers for MPI (Khandhar et al. 2017). Moreover, Orendorff et al. presented the first
three-dimensional imaging of the initial stage of traumatic brain injury and
corresponding hematoma in the closed skull via utilization of SPIO in MPI modality.
This study demonstrated the potential of MPI modality reinforced with MNPs in
noninvasive diagnosis of internal bleeding for patients suffering from trauma in the
emergency setting and thereby, assist in differentiating between mild and moderate
injuries. Thus, MPI-based device can be harnessed for the determination of location,
severity, and depth of the bleeding from the closed skull (Orendorff et al. 2017).
Additionally, Arami et al. presented a strategy for targeting the cancerous cells
using IONPs coated by biocompatible PMAO-PEG copolymer molecules, which
were further conjugated to lactoferrin to enhance the tumor-targeting activity of
IONPs. Afterwards, external magnetic field was applied and MPI generated three-
dimensional images from only nanoparticles that were embedded in tissues, based on
their intrinsic magnetic responses. This first preclinical study of cancer-targeted NPs
using a MPI system paves the way to explore new strategies for the diagnosis of
cancer (Arami et al. 2017).
24.4
Magnetic Nanoparticles for Biosensing Applications
A biosensor is a potential device capable of converting biological event into an easily
detectable signal. Biosensors comprise three parts: a biorecognition element
(antibodies, nucleic acids, cell receptors, enzymes, etc.), transducer (physicochemi-
cal, optical, piezoelectric, and chemical), and signal processor. Firstly, biosensing of
analyte entails the attachment of biorecognition element onto the surface of the
signal transducer, accompanied by robust interaction of biorecognition element with
the target analyte, and, finally, generation of an optical or electric signal by the
transducer. Moreover, the biomolecule immobilization is the defining parameter for
controlling the performance of biosensor.
In this regard, MNPs provide a suitable platform for the immobilization of
enzymes/biomolecules owing to their high surface area, biocompatibility, and easy
amenability of surface functional groups. The efficacy of MNP towards in vivo
studies can be epitomized basically by three strategies. The first strategy involves
magnetic preconcentration of an analyte where one can preconcentrate the analyte
via interaction between MNPs and analyte. In this manner, analyte bonded to MNPs
can be attracted onto the surface of the sensor with the application of gradient
magnetic field, and thus, analyte can be detected with minimal interferences from
the sample matrix. Another method emphasizes the involvement of functionalized
MNPs as tags for the visualization and selective detection of immunocomplexes with
a target analyte. The third approach involves the integration of MNPs into the
transducer material or the surface functionalization of the sensor for the amplifica-
tion of the output signal (Farka et al. 2017).
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