Functionalized micro/nanomotors having immobilized biological molecules provide excellent and powerful tools for the detection of target molecules. Based on surface modifications and mobilities of micromotors, we report herein a new experimental design of high-speed, self-propelled and plasma modified micromotors for biomedical applications. Within this scope, in the first step, poly (3,4-ethylenedioxythiophene) (PEDOT) was in-situ synthesized onto W5O14 (tungsten trioxide) wires by using radio frequency (RF) rotating plasma reactor. Then, W5O14/PEDOT-Platinum (Pt) hybrid micromotors were fabricated by using magnetron sputtering technique. The detection of miRNA-21 was performed using both single-stranded DNA (ssDNA) (probe DNA) immobilized W5O14-Pt and W5O14/PEDOT-Pt micromotors. The fluorescence signals were determined after hybridization of probe DNA immobilized these novel W5O14-Pt and W5O14/PEDOT-Pt micromotors with different molar concentrations of the synthetic target (6-carboxyfluorescein dye (FAM)-labeled miRNA-21). The changes in the micromotor speeds after the hybridization process were also evaluated. W5O14/PEDOT-Pt micromotors presented better sensor properties compared to the W5O14-Pt micromotors. A good linearity for miRNA-21 concentration between 0.1 nM and 100 nM was obtained for these micromotors based on their fluorescence intensities. The detection limit was found as 0.028 nM for W5O14/PEDOT-Pt micromotors (n = 3). Thus, sensor and motor characteristics of the W5O14-Pt micromotors were improved by RF plasma enhanced PEDOT coatings. The new catalytic W5O14 based micromotors demonstrated here had great potential for the development of sensitive and simple sensing platforms for detection of miRNA-21.
Keywords: Micromotor; Nanowire; PEDOT; RF magnetron sputter; RF rotating plasma; W(5)O(14).
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