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Scalable trapping of single nanosized extracellular vesicles using plasmonics

Chuchuan Hong, Justus C. Ndukaife

2023Nature Communications38 citationsDOIOpen Access PDF

Abstract

Heterogeneous nanoscale extracellular vesicles (EVs) are of significant interest for disease detection, monitoring, and therapeutics. However, trapping these nano-sized EVs using optical tweezers has been challenging due to their small size. Plasmon-enhanced optical trapping offers a solution. Nevertheless, existing plasmonic tweezers have limited throughput and can take tens of minutes for trapping for low particle concentrations. Here, we present an innovative approach called geometry-induced electrohydrodynamic tweezers (GET) that overcomes these limitations. GET generates multiple electrohydrodynamic potentials, allowing parallel transport and trapping of single EVs within seconds. By integrating nanoscale plasmonic cavities at the center of each GET trap, single EVs can be placed near plasmonic cavities, enabling instant plasmon-enhanced optical trapping upon laser illumination without detrimental heating effects. These non-invasive scalable hybrid nanotweezers open new horizons for high-throughput tether-free plasmon-enhanced single EV trapping and spectroscopy. Other potential areas of impact include nanoplastics characterization, and scalable hybrid integration for quantum photonics.

Topics & Concepts

PlasmonOptical tweezersTweezersTrappingNanotechnologyNanoscopic scaleMaterials scienceOptoelectronicsPhotonicsOpticsPhysicsBiologyEcologyMicrofluidic and Bio-sensing TechnologiesGold and Silver Nanoparticles Synthesis and ApplicationsOrbital Angular Momentum in Optics
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