What question did this study set out to answer?

To develop a cascaded photonic-plasmonic strategy for enhancing the spatial reach and sensitivity of surface-enhanced Raman scattering (SERS) in large biological targets.

May 15, 2026Open Access

From hotspots to hotspaces: Cascaded photonic-plasmonic coupling for SERS-based deep profiling of whole small extracellular vesicles

Key Points

To develop a cascaded photonic-plasmonic strategy for enhancing the spatial reach and sensitivity of surface-enhanced Raman scattering (SERS) in large biological targets.
Integrated dielectric silicon dioxide microspheres with a plasmonic nanoarray
Generated subdiffraction nanojets through photonic coupling
Conducted in silico simulations and experimental validation for signal enhancement
Achieved ~20-fold enhancements in signal intensity compared to conventional methods
Classifier accuracy for colorectal cancer extracellular vesicles reached 99.8%
Demonstrated spatially extended electromagnetic hotspaces exceeding 110 nm across.

Abstract

The spatial confinement of electromagnetic hotspots ( 10 6 , a regime inaccessible to conventional surface-enhanced Raman scattering (SERS) platforms. In silico simulations and experiments reveal ~20-fold enhancements in signal intensity and spatial reach compared to conventional nanoarrays. As a proof of concept, we demonstrate ultrasensitive, label-free classification of extracellular vesicles, 80 to 200 nm in diameter, derived from patients with colorectal cancer with 99.8% accuracy, surpassing traditional SERS (<87.5%). More broadly, this cascaded excitation strategy shifts the emphasis from nanogap optimization to the engineering of spatially extended fields through hybrid light-focusing architectures, enabling advances in spectroscopy, biosensing, nanophotonics, and diagnostics.

From hotspots to hotspaces: Cascaded photonic-plasmonic coupling for SERS-based deep profiling of whole small extracellular vesicles

Key Points

Abstract

Cite This Study