Novel Aptasensor Platform Based on Ratiometric Surface-Enhanced
Raman Spectroscopy
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Abstract
A novel aptasensor
platform has been developed for quantitative
detection of adenosine triphosphate (ATP) based on a ratiometric surface-enhanced
Raman scattering (SERS) strategy. The thiolated 3′-Rox-labeled
complementary DNA (cDNA) is first immobilized on the gold nanoparticle
(AuNP) surface and then hybridizes with the 3′-Cy5-labeled
ATP-binding aptamer probe (Cy5-aptamer) to form a rigid double-stranded
DNA (dsDNA), in which the Cy5 and Rox Raman labels are used to produce
the ratiometric Raman signals. In the presence of ATP, the Cy5-aptamer
is triggered the switching of aptamer to form the aptamer–ATP
complex, leading to the dissociation of dsDNA, and the cDNA is then
formed a hairpin structure. As a result, the Rox labels are close
to the AuNP surface while the Cy5 labels are away from. Therefore,
the intensity of SERS signal from Rox labels increases while that
from Cy5 labels decreases. The results show that the ratio between
the Raman intensities of Rox labels and Cy5 labels is well linear
with the ATP concentrations in the range from 0.1 to 100 nM, and the
limit of detection reaches 20 pM, which is much lower than that of
other methods for ATP detection and is also lower than that of SERS
aptasensor for ATP detection. The proposed strategy provides a new
reliable platform for the construction of SERS biosensing methods
and has great potential to be a general method for other aptamer systems