Quantum Dots as Simultaneous Acceptors and Donors in Time-Gated Förster Resonance Energy Transfer Relays: Characterization and Biosensing

Algar, W. Russ; Wegner, David; Huston, Alan L.; Blanco‐Canosa, Juan B.; Stewart, Michael H.; Armstrong, Anika; Dawson, Philip E.; Hildebrandt, Niko; Medintz, Igor L.

doi:10.1021/ja210162f

Cited by 236 publications

(297 citation statements)

References 67 publications

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“…They have been used on both QDs and AuNPs (54). A short sequence of histidine amino acids can be included in a recombinant protein (54), in a peptide sequence (55), or as part of an oligonucleotide construct (56), and its high affinity for metal nanoparticle surfaces allows attachment with excellent control over number and orientation of attached species. The many emerging highly site-or sequence-selective conjugation techniques, such as click reactions (57,58), strain-promoted cycloadditions (59), and enzyme-mediated ligations (60,61), are excellent prospects for nanoparticle bioconjugation, as they offer rapid, efficient, and strong binding.…”

Section: Biosensing Mechanismsmentioning

confidence: 99%

Colloidal nanoparticles as advanced biological sensors

Howes

Chandrawati

Stevens

2014

Science

878

686

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Colloidal nanoparticle biosensors have received intense scientific attention and offer promising applications in both research and medicine. We review the state of the art in nanoparticle development, surface chemistry, and biosensing mechanisms, discussing how a range of technologies are contributing toward commercial and clinical translation. Recent examples of success include the ultrasensitive detection of cancer biomarkers in human serum and in vivo sensing of methyl mercury. We identify five key materials challenges, including the development of robust mass-scale nanoparticle synthesis methods, and five broader challenges, including the use of simulations and bioinformatics-driven experimental approaches for predictive modeling of biosensor performance. The resultant generation of nanoparticle biosensors will form the basis of high-performance analytical assays, effective multiplexed intracellular sensors, and sophisticated in vivo probes.Evolution has given rise to organisms of staggering complexity. Our now extensive knowledge of biological systems pales in comparison to the remaining mysteries. Unraveling these requires tools that probe the molecular machinery of life and provide detailed feedback on complex networks of subtle interactions. Such tools are cornerstones of biomedical research and practice, and improvements in these lead directly to a better understanding of fundamental biology, monitoring of health, and diagnosis of disease. Colloidal nanoparticle biosensors are a class of biological probe that will not only yield improved biological sensing but also provide a step change in our ability to probe the biomolecular realm. Nanoparticles can act as high-performance sensors because nanomaterials exhibit unique and useful behaviors not present in their bulk form: for example, bright tunable fluorescence from semiconductor nanoparticles and localized surface plasmon resonance (LSPR) phenomena in metallic nanoparticles. These particles exhibit intense responses to incident light (or other stimuli), and the ability to modulate this response by interaction with target analytes makes them excellent biosensor signal transducers. Outputs can be quantitative or qualitative depending on the functionality of

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Section: Biosensing Mechanismsmentioning

confidence: 99%

Colloidal nanoparticles as advanced biological sensors

Howes

Chandrawati

Stevens

2014

Science

878

686

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“…The time-gated FRET relay was applied in a model two-plex DNA hybridization assay (Fig. 5B), 105 and in two-plex assays for protease activity. 136 The latter assay included tracking the activation of an inactive pro-protease by another protease, where the activity of both the upstream activating protease and downstream activated protease were quantitatively measured.…”

Section: Bioanalysis and Bioimaging With Quantum Dotsmentioning

confidence: 99%

Quantum Dots in Bioanalysis: A Review of Applications across Various Platforms for Fluorescence Spectroscopy and Imaging

2013

Self Cite

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Semiconductor quantum dots (QDs) are brightly luminescent nanoparticles that have found numerous applications in bioanalysis and bioimaging. In this review, we highlight recent developments in these areas in the context of specific methods for fluorescence spectroscopy and imaging. Following a primer on the structure, properties, and biofunctionalization of QDs, we describe select examples of how QDs have been used in combination with steady-state or time-resolved spectroscopic techniques to develop a variety of assays, bioprobes, and biosensors that function via changes in QD photoluminescence intensity, polarization, or lifetime. Some special attention is paid to the use of Förster resonance energy transfer-type methods in bioanalysis, including those based on bioluminescence and chemiluminescence. Direct chemiluminescence, electrochemiluminescence, and charge transfer quenching are similarly discussed. We further describe the combination of QDs and flow cytometry, including traditional cellular analyses and spectrally encoded barcode-based assay technologies, before turning our attention to enhanced fluorescence techniques based on photonic crystals or plasmon coupling. Finally, we survey the use of QDs across different platforms for biological fluorescence imaging, including epifluorescence, confocal, and twophoton excitation microscopy; single particle tracking and fluorescence correlation spectroscopy; super-resolution imaging; near-field scanning optical microscopy; and fluorescence lifetime imaging microscopy. In each of the above-mentioned platforms, QDs provide the brightness needed for highly sensitive detection, the photostability needed for tracking dynamic processes, or the multiplexing capacity needed to elucidate complex systems. There is a clear synergy between advances in QD materials and spectroscopy and imaging techniques, as both must be applied in concert to achieve their full potential.

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“…The environmental factors such as the presence of particular proteins, ions or pH change can also influence the overall fluoroassay performance. Recently, a very interesting example of a (FRET relay)-based immunoassay has been presented, 31,32 in which FRET first proceeds from a lanthanide complex to QD and then from QD to a dye. The here presented complex can be applied in such systems to improve FRET efficiency and, therefore, sensitivity and robustness for such assay.…”

Section: Resultsmentioning

confidence: 99%

Photophysical evaluation of a new functional terbium complex in FRET-based time-resolved homogenous fluoroassays

Cywiński

Nono²,

Charbonnière³

et al. 2014

Phys. Chem. Chem. Phys.

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A new functional luminescent lanthanide complex (LLC) has been synthesized with terbium as a central lanthanide ion and biotin as a functional moiety. Unlike in typical lanthanide complexes assembled via carboxylic moieties, in the presented complex, four phosphate groups are chelating the central lanthanide ion. This special chemical assembly enhances the complex stability in phosphate buffers conventionally used in biochemistry. The complex synthesis strategy and photophysical properties are described as well as the performance in time-resolved Förster Resonance Energy Transfer (FRET) assays. In those assays, this biotin-LLC transferred energy either to acceptor organic dyes (Cy5 or AF680) labelled on streptavidin or to quantum dots (QD655 or QD705) surfacefunctionalised with streptavidins. The permanent spatial donor-acceptor proximity is assured through strong and stable biotin-streptavidin binding. The energy transfer is evidenced from the quenching observed in donor emission and from a decrease in donor luminescence decay, both associated with simultaneous increase in acceptor intensity and in the decay time. The dye-based assays are realised in TRIS and in PBS, whereas QD-based systems are studied in borate buffer. The delayed emission analysis allows for quantifying the recognition process and for auto-fluorescence-free detection, which is particularly relevant for application in bioanalysis. In accordance with Förster theory, Förster-radii (R 0 ) were found to be around 60 Å for organic dyes and around 105 Å for QDs. The FRET efficiency (Z) reached 80% and 25% for dye and QD acceptors, respectively. Physical donor-acceptor distances (r) have been determined in the range 45-60 Å for organic dye acceptors, while for acceptor QDs between 120 Å and 145 Å. This newly synthesised biotin-LLC extends the class of highly sensitive analytical tools to be applied in the bioanalytical methods such as time-resolved fluoroimmunoassays (TR-FIA), luminescent imaging and biosensing.

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Quantum Dots as Simultaneous Acceptors and Donors in Time-Gated Förster Resonance Energy Transfer Relays: Characterization and Biosensing

Cited by 236 publications

References 67 publications

Colloidal nanoparticles as advanced biological sensors

Colloidal nanoparticles as advanced biological sensors

Quantum Dots in Bioanalysis: A Review of Applications across Various Platforms for Fluorescence Spectroscopy and Imaging

Photophysical evaluation of a new functional terbium complex in FRET-based time-resolved homogenous fluoroassays

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