Label-free and reagentless electrochemical detection of microRNAs using a conducting polymer nanostructured by carbon nanotubes: Application to prostate cancer …
Biosensors and Bioelectronics, 2013•Elsevier
In this paper, a label-free and reagentless microRNA sensor based on an interpenetrated
network of carbon nanotubes and electroactive polymer is described. The nanostructured
polymer film presents very well-defined electroactivity in neutral aqueous medium in the
cathodic potential domain from the quinone group embedded in the polymer backbone.
Addition of microRNA miR-141 target (prostate cancer biomarker) gives a “signal-on”
response, ie a current increase due to enhancement of the polymer electroactivity. On the …
network of carbon nanotubes and electroactive polymer is described. The nanostructured
polymer film presents very well-defined electroactivity in neutral aqueous medium in the
cathodic potential domain from the quinone group embedded in the polymer backbone.
Addition of microRNA miR-141 target (prostate cancer biomarker) gives a “signal-on”
response, ie a current increase due to enhancement of the polymer electroactivity. On the …
Abstract
In this paper, a label-free and reagentless microRNA sensor based on an interpenetrated network of carbon nanotubes and electroactive polymer is described. The nanostructured polymer film presents very well-defined electroactivity in neutral aqueous medium in the cathodic potential domain from the quinone group embedded in the polymer backbone. Addition of microRNA miR-141 target (prostate cancer biomarker) gives a “signal-on” response, i.e. a current increase due to enhancement of the polymer electroactivity. On the contrary, non-complementary miRNAs such as miR-103 and miR-29b-1 do not lead to any significant current change. A very low detection limit of ca. 8 fM is achieved with this sensor.
Elsevier
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