While nanoscale quantum emitters are effective tags for measuring biomolecular interactions, their utilities for applications that demand single-unit observations are limited by the requirements for large numerical aperture (NA) objectives, fluorescence intermittency, and poor photon collection efficiency resulted from omnidirectional emission. Here, we report a nearly 3000-fold signal enhancement achieved through multiplicative effects of enhanced excitation, highly directional extraction, quantum efficiency improvement, and blinking suppression through a photonic crystal (PC) surface. The approach achieves single quantum dot (QD) sensitivity with high signal-to-noise ratio, even when using a low-NA lens and an inexpensive optical setup. The blinking suppression capability of the PC improves the QDs on-time from 15% to 85% ameliorating signal intermittency. We developed an assay for cancer-associated miRNA biomarkers with single-molecule resolution, single-base mutation selectivity, and 10-attomolar detection limit. Additionally, we observed differential surface motion trajectories of QDs when their surface attachment stringency is altered by changing a single base in a cancer-specific miRNA sequence.
One of the frontiers in the field of biosensors is the ability to quantify specific target molecules with enough precision to count individual units in a test sample, and to...
We demonstrate a rapid and ultrasensitive assay for protein quantification through the nanoparticle–photonic crystal coupling embedded in microfluidic cartridges.
Several applications in health diagnostics, food, safety, and environmental monitoring require rapid, simple, selective, and quantitatively accurate viral load monitoring. Here, we introduce the first label-free biosensing method that rapidly detects and quantifies intact virus in human saliva with single-virion resolution. Using pseudotype SARS-CoV-2 as a representative target, we immobilize aptamers with the ability to differentiate active from inactive virions on a photonic crystal, where the virions are captured through affinity with the spike protein displayed on the outer surface. Once captured, the intrinsic scattering of the virions is amplified and detected through interferometric imaging. Our approach analyzes the motion trajectory of each captured virion, enabling highly selective recognition against nontarget virions, while providing a limit of detection of 1 × 10 3 copies/mL at room temperature. The approach offers an alternative to enzymatic amplification assays for point-of-collection diagnostics.
Rapid,
ultrasensitive, and selective quantification of circulating
microRNA (miRNA) biomarkers in body fluids is increasingly deployed
in early cancer diagnosis, prognosis, and therapy monitoring. While
nanoparticle tags enable detection of nucleic acid or protein biomarkers
with digital resolution and subfemtomolar detection limits without
enzymatic amplification, the response time of these assays is typically
dominated by diffusion-limited transport of the analytes or nanotags
to the biosensor surface. Here, we present a magnetic activate capture
and digital counting (mAC+DC) approach that utilizes magneto-plasmonic
nanoparticles (MPNPs) to accelerate single-molecule sensing, demonstrated
by miRNA detection via toehold-mediated strand displacement.
Spiky Fe3O4@Au MPNPs with immobilized target-specific
probes are “activated” by binding with miRNA targets,
followed by magnetically driven transport through the bulk fluid toward
nanoparticle capture probes on a photonic crystal (PC). By spectrally
matching the localized surface plasmon resonance of the MPNPs to the
PC-guided resonance, each captured MPNP locally quenches the PC reflection
efficiency, thus enabling captured MPNPs to be individually visualized
with high contrast for counting. We demonstrate quantification of
the miR-375 cancer biomarker directly from unprocessed human serum
with a 1 min response time, a detection limit of 61.9 aM, a broad
dynamic range (100 aM to 10 pM), and a single-base mismatch selectivity.
The approach is well-suited for minimally invasive biomarker quantification,
enabling potential applications in point-of-care testing with short
sample-to-answer time.
In recent years, the biosensor research community has made rapid progress in the development of nanostructured materials capable of amplifying the interaction between light and biological matter. A common objective is to concentrate the electromagnetic energy associated with light into nanometer-scale volumes that, in many cases, can extend below the conventional Abbé diffraction limit. Dating back to the first application of surface plasmon resonance (SPR) for label-free detection of biomolecular interactions, resonant optical structures, including waveguides, ring resonators, and photonic crystals, have proven to be effective conduits for a wide range of optical enhancement effects that include enhanced excitation of photon emitters (such as quantum dots, organic dyes, and fluorescent proteins), enhanced extraction from photon emitters, enhanced optical absorption, and enhanced optical scattering (such as from Raman-scatterers and nanoparticles). The application of photonic metamaterials as a means for enhancing contrast in microscopy is a recent technological development. Through their ability to generate surface-localized and resonantly enhanced electromagnetic fields, photonic metamaterials are an effective surface for magnifying absorption, photon emission, and scattering associated with biological materials while an imaging system records spatial and temporal patterns. By replacing the conventional glass microscope slide with a photonic metamaterial, new forms of contrast and enhanced signal-to-noise are obtained for applications that include cancer diagnostics, infectious disease diagnostics, cell membrane imaging, biomolecular interaction analysis, and drug discovery. This paper will review the current state of the art in which photonic metamaterial surfaces are utilized in the context of microscopy.
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