Plasmonic Nanoprobes for Stimulated Emission Depletion Nanoscopy

Cortés, Emiliano; Huidobro, Paloma A.; Sinclair, Hugo G.; Guldbrand, Stina; Peveler, William J.; Davies, Timothy; Parrinello, Simona; Görlitz, Frederik; Dunsby, Chris; Neil, Mark A. A.; Sivan, Yonatan; Parkin, Ivan P.; French, Paul M. W.; Maier, Stefan A.

doi:10.1021/acsnano.6b06361

Cited by 32 publications

(47 citation statements)

References 53 publications

(124 reference statements)

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“…Urban et al reported STED microscopy with 20 nm gold nanospheres coated with fluorescent silica and achieved approximately half the intensity of conventional STED based on dyes alone . Similar result was also obtained in gold nanorods reported by Cortes et al Although the methods reported above were beneficial for improving the resolution of STED nanoscopy, the required STED laser power was still very high. Quite recently, super‐resolution imaging (∆ x ≈ 28 nm) with an extremely low‐intensity STED beam was achieved using upconversion nanoparticles (UCNPs) as probes due to their exceptionally high stimulated‐emission efficiency .…”

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confidence: 56%

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots

Yan

Zhao

et al. 2018

Advanced Materials

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Stimulated emission depletion (STED) nanoscopy is one of the most promising super-resolution imaging techniques for microstructure imaging. Commercial CdSe@ZnS quantum dots are used as STED probes and ≈50 nm lateral resolution is obtained. Compared with other quantum dots, perovskite CsPbBr nanoparticles (NPs) possess higher photoluminescence quantum yield and larger absorption cross-section, making them a more effective probe for STED nanoscopy. In this study, CsPbBr NPs are used as probes for STED nanoscopy imaging. The fluorescence intensity of the CsPbBr sample is hardly weakened at all after 200 min irradiation with a 39.8 mW depletion laser, indicating excellent photobleaching resistance of the CsPbBr NPs. The saturation intensity of the CsPbBr NPs is extremely low and estimated to be only 0.4 mW (0.126 MW cm ). Finally, an ultrahigh lateral resolution of 20.6 nm is obtained for a single nanoparticle under 27.5 mW STED laser irradiation in CsPbBr -based STED nanoscopy imaging, which is a tenfold improvement compared with confocal microscopy. Because of its high fluorescence stability and ultrahigh resolution under lower depletion power, CsPbBr -assisted STED nanoscopy has great potential to investigate microstructures that require super-resolution and long-term imaging.

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confidence: 56%

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots

Yan

Zhao

et al. 2018

Advanced Materials

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“…This near‐field enhancement yields high depletion efficiencies of attached dyes even with low power lasers, provided that the depletion wavelength is close to the plasmon peak . As a note of caution, heating and heat‐induced movement of the metallic NPs may pose a problem for STED nanoscopy at depletion powers above ∼2 MW/cm 2 …”

Section: Nanoparticles For Super‐resolution Fluorescence Microscopymentioning

confidence: 98%

“…Instead of increasing the number of fluorophores in a NP, Maier and co‐workers amplified their luminescence by using electromagnetic field enhancement effected by plasmonic metal NPs. Light can resonantly excite collective oscillations of conduction electrons at the surface (surface plasmons) of a metallic NPs, thereby causing a dramatic increase of the local electric field.…”

Section: Nanoparticles For Super‐resolution Fluorescence Microscopymentioning

confidence: 99%

Nanoparticle Probes for Super‐Resolution Fluorescence Microscopy

Lin

Nienhaus

2018

ChemNanoMat

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The Abbe resolution limit of ∼200 nm of conventional light‐optical microscopy greatly restricts the observation of subcellular processes. This Abbe resolution barrier has been surpassed by super‐resolution fluorescence microscopy methods that use time as an additional dispersing dimension. Light irradiation can be employed to externally control the emission properties of the luminescent markers, or spontaneous fluctuations of the emission of individual emitters can be analyzed. Here we review the development and application of light‐emitting nanoscale particles for super‐resolution imaging and discuss their (photo)physical and (photo)chemical characteristics to offer guidance in the selection of the optimal nanoparticle marker for an intended super‐resolution imaging experiment.

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“…microfluidics, electrochemistry 2 ) with components for fluorescence spectroscopy and imaging; spatial and temporal resolution across many orders of magnitude (e.g. super-resolution imaging, 3,4 dynamic tracking); multiparametric encoding of information in the form of intensity, wavelength, anisotropy, and lifetime; and potential to respond to physicochemical attributes of the local environment (e.g. temperature, 5 viscosity, 6 pH 7 ) and molecular interactions.…”

Section: Introductionmentioning

confidence: 99%

More Than a Light Switch: Engineering Unconventional Fluorescent Configurations for Biological Sensing

Peveler

Algar

2018

ACS Chem. Biol.

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Fluorescence is a powerful and sensitive tool in biological detection, used widely for cellular imaging and in vitro molecular diagnostics. Over time, three prominent conventions have emerged in the design of fluorescent biosensors: a sensor is ideally specific for its target, only one fluorescence signal turns on or off in response to the target, and each target requires its own sensor and signal combination. These are conventions but not requirements, and sensors that break with one or more of these conventions can offer new capabilities and advantages. Here, we review "unconventional" fluorescent sensor configurations based on fluorescent dyes, proteins, and nanomaterials such as quantum dots and metal nanoclusters. These configurations include multifluorophore Förster resonance energy transfer (FRET) networks, temporal multiplexing, photonic logic, and cross-reactive arrays or "noses". The more complex but carefully engineered biorecognition and fluorescence signaling modalities in unconventional designs are richer in information, afford greater multiplexing capacity, and are potentially better suited to the analysis of complex biological samples, interactions, processes, and diseases. We conclude with a short perspective on the future of unconventional fluorescent sensors and encourage researchers to imagine sensing beyond the metaphorical light bulb and light switch combination.

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Plasmonic Nanoprobes for Stimulated Emission Depletion Nanoscopy

Cited by 32 publications

References 53 publications

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots

Nanoparticle Probes for Super‐Resolution Fluorescence Microscopy

More Than a Light Switch: Engineering Unconventional Fluorescent Configurations for Biological Sensing

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Plasmonic Nanoprobes for Stimulated Emission Depletion Nanoscopy

Cited by 32 publications

References 53 publications

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr3 Quantum Dots

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr3 Quantum Dots

Nanoparticle Probes for Super‐Resolution Fluorescence Microscopy

More Than a Light Switch: Engineering Unconventional Fluorescent Configurations for Biological Sensing

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Product

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Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots

Low‐Saturation‐Intensity, High‐Photostability, and High‐Resolution STED Nanoscopy Assisted by CsPbBr₃ Quantum Dots