A Simple Separation Method of the Protein and Polystyrene Bead-Labeled Protein for Enhancing the Performance of Fluorescent Sensor

Overview

Journal J Anal Methods Chem

Publisher Wiley

Specialty Chemistry

Date 2018 Aug 18

PMID 30116650

Authors

Hye Jin Kim

Dong-Hoon Kang

Seung-Hoon Yang

Eunji Lee

Taewon Ha

Byung Chul Lee

Youngbaek Kim

Kyo Seon Hwang

Hyun-Joon Shin

Jinsik Kim

Affiliations

Soon will be listed here.

Abstract

Dielectrophoresis- (DEP-) based separation method between a protein, amyloid beta 42, and polystyrene (PS) beads in different microholes was demonstrated for enhancement of performance for bead-based fluorescent sensor. An intensity of ∇|| was relative to a diameter of a microhole, and the diameters of two microholes for separation between the protein and PS beads were simulated to 3 m and 15 m, respectively. The microholes were fabricated by microelectromechanical systems (MEMS). The separation between the protein and the PS beads was demonstrated by comparing the average intensity of fluorescence (AIF) by each molecule. Relative AIF was measured in various applying voltage and time conditions, and the conditions for allocating the PS beads into 15 m hole were optimized at 80 mV and 15 min, respectively. In the optimized condition, the relative AIF was observed approximately 4.908 ± 0.299. Finally, in 3 m and 15 m hole, the AIFs were approximately 3.143 and -1.346 by 2 nm of protein and about -2.515 and 4.211 by 30 nm of the PS beads, respectively. The results showed that 2 nm of the protein and 30 nm of PS beads were separated by DEP force in each microhole effectively, and that our method is applicable as a new method to verify an efficiency of the labeling for bead-based fluorescent sensor ∇||.

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