Title :
Optical Detection of Lead and Potassium Ions Using a Quantum-Dot-Based Aptamer Nanosensor
Author :
Meshik, Xenia ; Ke Xu ; Dutta, Maitreyee ; Stroscio, Michael A.
Author_Institution :
Bioeng. Dept., Univ. of Illinois at Chicago, Chicago, IL, USA
Abstract :
Quantum-dot (QD) based nanosensors can be used to detect a wide range of molecules. This study examined a nanosensor comprised of thrombin binding aptamer (TBA) with 700NC InGaP QD on the 5 ´ terminus and an Au nanoparticle quencher on the 3 ´ terminus. Both K+ and Pb2+ bind to TBA, resulting in a conformational change that brings the Au quencher closer to the QD. Photoluminescence measurements indicated a decrease in fluorescence corresponding to an increase in either K+ or Pb2+ concentration. For healthy blood serum K+ concentrations (3.5-5 mM), the beacon exhibited 15-17% quenching efficiency. Pb2+ concentration of 0.48 μM, the threshold for toxicity in serum, yielded 14% quenching. The beacon´s ability to detect changes in ion levels in a critical range of concentrations can make it an effective diagnostic tool.
Keywords :
biosensors; lead; nanosensors; photoluminescence; potassium; quantum dots; K+; Pb2+; aptamer nanosensor; conformational change; fluorescence; lead ion optical detection; nanoparticle quencher; photoluminescence; potassium ion optical detection; quantum dot; quenching efficiency; serum; thrombin binding aptamer; toxicity threshold; Fluorescence; Gold; Ions; Nanobioscience; Nanoparticles; Optical sensors; DNA; gold nanoparticles; ion detection; photoluminescence; quantum dots (QD); thrombin binding aptamer (TBA);
Journal_Title :
NanoBioscience, IEEE Transactions on
DOI :
10.1109/TNB.2014.2317315
