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Demonstration of intracellular real-time molecular quantification via FRET-enhanced optical microcavity

Yaping Wang, Marion Lang, Jinsong Lu, Mingqian Suo, Mengcong Du, Yubin Hou, Xiuhong Wang, Lingzhi Zhao

2022Nature Communications34 citationsDOIOpen Access PDF

Abstract

Single cell analysis is crucial for elucidating cellular diversity and heterogeneity as well as for medical diagnostics operating at the ultimate detection limit. Although superbly sensitive biosensors have been developed using the strongly enhanced evanescent fields provided by optical microcavities, real-time quantification of intracellular molecules remains challenging due to the extreme low quantity and limitations of the current techniques. Here, we introduce an active-mode optical microcavity sensing stage with enhanced sensitivity that operates via Förster resonant energy transferring (FRET) mechanism. The mutual effects of optical microcavity and FRET greatly enhances the sensing performance by four orders of magnitude compared to pure Whispering gallery mode (WGM) microcavity sensing system. We demonstrate distinct sensing mechanism of FRET-WGM from pure WGM. Predicted lasing wavelengths of both donor and acceptor by theoretical calculations are in perfect agreement with the experimental data. The proposed sensor enables quantitative molecular analysis at single cell resolution, and real-time monitoring of intracellular molecules over extended periods while maintaining the cell viability. By achieving high sensitivity at single cell level, our approach provides a path toward FRET-enhanced real-time quantitative analysis of intracellular molecules.

Topics & Concepts

Förster resonance energy transferWhispering-gallery waveResonant inductive couplingBiosensorIntracellularMaterials scienceOptical microcavitySensitivity (control systems)Single-cell analysisOptoelectronicsBiophysicsNanotechnologyFluorescenceChemistryPhysicsOpticsEnergy transferChemical physicsCellLaserElectronic engineeringBiologyResonatorEngineeringBiochemistryPhotonic and Optical DevicesPhotonic Crystals and ApplicationsNeural Networks and Reservoir Computing