Plasmonic nano-aperture label-free imaging

TL;DR

PANORAMA is a novel plasmonic imaging technique that achieves diffraction-limited resolution, high surface sensitivity, and dense sampling using a standard bright-field microscope, enabling detailed analysis of nanoparticles and biological particles.

Contribution

It introduces a bright-field, near-field plasmonic imaging method that overcomes limitations of SPR and LSPR imaging, providing high resolution, sensitivity, and dense sampling with simple equipment.

Findings

Resolves nanoparticles down to 25 nm size.

Counts individual nanoparticles in clusters.

Monitors nanoparticle approach in real-time.

Abstract

Label-free observation of nanoparticles by far-field optical microscopy is challenging because their ability to scatter or absorb light dramatically diminishes with decreasing size. Surface plasmon resonance (SPR) and localized surface plasmon resonance (LSPR) imaging have shown promises and respective limitations. For instance, it is challenging to achieve diffraction-limited resolution in SPR imaging; its refractive index sensitivity is not as localized as desired. LSPR imaging is typically employed with dark-field microscopy on sparse noble metal nanostructures, leading to low light throughput and incomplete imaging. Here we demonstrate ultra near-field index modulated PlAsmonic NanO-apeRture lAbel-free iMAging (PANORAMA) that addresses existing issues for both SPR and LSPR imaging. PANORAMA produces diffraction-limited lateral resolution with higher surface sensitivity compared to SPR. Its system configuration is identical to a standard bright-field microscope using a trans-illumination tungsten-halogen lamp instead of a laser or other high-intensity light sources. Additionally, PANORAMA addresses the sparse sampling issue in LSPR imaging by achieving dense sampling with a large imaging fill factor. The bright-field approach provides much higher light throughput compared to dark-field microscopy. Overall, our technique can provide a panoramic view both laterally and longitudinally - overcoming the lack of imaging depth for both SPR and LSPR imaging and the insufficient lateral sampling for LSPR imaging. We have demonstrated that PANORAMA can size single nanoparticle down to 25 nm, count individual nanoparticles in a cluster, and dynamically monitor single nanoparticle approaching the plasmonic surface down to the millisecond timescale. PANORAMA is potentially useful in single biological nanoparticle analysis of exosomes and viruses.