Bei Zheng, Ya-Feng Kang, Ting Zhang, Cheng-Yu Li, Sha Huang, Zhi-Ling Zhang, Qiong-Shui Wu, Chu-Bo Qi, Dai-Wen Pang, and Hong-Wu Tang
To enhance signal acquisition stability and diminish background interference for conventional flow bead-based fluorescence detection methods, we demonstrate here an exceptional microfluidic chip assisted platform by integrating near-infrared optical tweezers with upconversion luminescence encoding. For the former, a single 980 nm laser is employed to perform optical trapping and concurrently excite upconversion luminescence, avoiding the fluctuation of the signals and the complexity of the apparatus. By virtue of the favorable optical properties of upconversion nanoparticles (UCNPs), the latter is carried out by employing two-color UCNPs (Er-UCNPs and Tm-UCNPs) with negligible spectral overlaps. With the assistance of the double key techniques, we fabricated complex microbeads referred to a UCNPs–miRNAs–microbead sandwich construct by a one-step nucleic acid hybridization process and then obtained uniform terrace peaks for the automatic and simultaneous quantitative determination of miRNA-205 and miRNA-21 sequences with a detection limit of pM level on the basis of a special home-built flow bead platform. Furthermore, the technique was successfully applied for analyzing complex biological samples such as cell lysates and human tissue lysates, holding certain potential for disease diagnosis. In addition, it is expected that the flow platform can be utilized to investigate many other biomolecules of single cells and to allow analysis of particle heterogeneity in biological fluid by means of optical tweezers.
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