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Acceleration of Biomolecule Enrichment and Detection with Rotationally Motorized Opto-Plasmonic Microsensors and the Working Mechanism

Jianhe Guo, Zexi Liang, Yun Huang, Kwanoh Kim, Peter E. Vandeventer, Donglei Fan

2020ACS Nano24 citationsDOI

Abstract

Vigorous research efforts have advanced the state-of-the-art nanosensors with ultrahigh sensitivity for bioanalysis. However, a dilemmatic challenge remains: it is extremely difficult to obtain nanosensors that are both sensitive and high-speed for the detection of low-concentration molecules in aqueous samples. Herein, we report how the controlled mechanical rotation (or rotary motorization) of designed opto-plasmonic microsensors can substantially and robustly accelerate the enrichment and detection speed of deoxyribonucleic acid (DNA) with retained high sensitivity. At least 4-fold augmentation of the capture speed of DNA molecules is obtained from a microsensor rotating at 1200 rpm. Theoretical analysis and modeling shed light on the underlying working mechanism, governed by the molecule-motor-flow interaction as well as its application range and limitation. This work provides a device scheme that alleviates the dilemmatic challenge in biomolecule sensing and offers the understanding of the complex interactions of molecules and moving microobjects in suspension. The results may assist the rational design of efficient microrobotic systems for the capture, translocation, sensing, and release of biocargoes.

Topics & Concepts

NanosensorBiomoleculeNanotechnologyMaterials sciencePlasmonMechanism (biology)Sensitivity (control systems)MoleculeBioanalysisBiosensorBiological systemChemistryOptoelectronicsPhysicsElectronic engineeringBiologyEngineeringQuantum mechanicsOrganic chemistryMicro and Nano RoboticsOrbital Angular Momentum in OpticsMicrofluidic and Bio-sensing Technologies
Acceleration of Biomolecule Enrichment and Detection with Rotationally Motorized Opto-Plasmonic Microsensors and the Working Mechanism | Litcius