Energy Transfer Pathways in a Quantum Dot-Based Concentric FRET Configuration

Wu, Miao; Massey, Melissa; Petryayeva, Eleonora; Algar, W. Russ

doi:10.1021/acs.jpcc.5b08612

Cited by 28 publications

(56 citation statements)

References 62 publications

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“…The A555 PL is directly quenched by increasing A555-to-A647 FRET, and indirectly quenched through a reduction in the efficiency of QD-to-A555 FRET with increasingly competitive and efficient QD-to-A647 FRET. 537 Resolution of A555-to-A647 FRET requires either a correction for this competitive effect, or direct excitation of the A555 without excitation of the QD. 537 Experiments have shown that the A555-to-A647 E FRET depends strongly on N A647 , but its dependence on N A555 appears to be much smaller and is still unclear in its details.…”

Section: Aptamermentioning

confidence: 99%

Energy Transfer with Semiconductor Quantum Dot Bioconjugates: A Versatile Platform for Biosensing, Energy Harvesting, and Other Developing Applications

Spillmann²,

et al. 2016

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Luminescent semiconductor quantum dots (QDs) are one of the more popular nanomaterials currently utilized within biological applications. However, what is not widely appreciated is their growing role as versatile energy transfer (ET) donors and acceptors within a similar biological context. The progress made on integrating QDs and ET in biological configurations and applications is reviewed in detail here. The goal is to provide the reader with (1) an appreciation for what QDs are capable of in this context, (2) how this field has grown over a relatively short time span, and, in particular, (3) how QDs are steadily revolutionizing the development of new biosensors along with a myriad of other photonically active nanomaterial-based bioconjugates. An initial discussion of QD materials along with key concepts surrounding their preparation and bioconjugation is provided given the defining role these aspects play in the QDs ability to succeed in subsequent ET applications. The discussion is then divided around the specific roles that QDs provide as either Förster resonance energy transfer (FRET) or charge/electron transfer donor and/or acceptor. For each QD-ET mechanism, a working explanation of the appropriate background theory and formalism is articulated before examining their biosensing and related ET utility. Other configurations such as incorporation of QDs into multistep ET processes or use of initial chemical and bioluminescent excitation are treated similarly. ET processes that are still not fully understood such as QD interactions with gold and other metal nanoparticles along with carbon allotropes are also covered. Given their maturity, some specific applications ranging from in vitro sensing assays to cellular imaging are separated and discussed in more detail. Finally a perspective on how this field will continue to evolve is provided.

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Section: Aptamermentioning

confidence: 99%

Energy Transfer with Semiconductor Quantum Dot Bioconjugates: A Versatile Platform for Biosensing, Energy Harvesting, and Other Developing Applications

Spillmann²,

et al. 2016

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“…184,185 Case 4 has largely been explored in university and other research institutions to construct portable clinical analyzers. [513][514][515][516][517][518][519][520][521][522][523][524][525][526][527][528][529] The fluorescence and colorimetric test reagents for clinical assays and analyses are well-known and widely available. In principle, therefore, interfacing microfluidics and a wavelength-selective device to a smartphone camera, with appropriate software, produces a mobile clinical analyzer with built-in communications abilities.…”

Section: Smartphone Spectroscopymentioning

confidence: 99%

Portable Spectroscopy

Crocombe¹

2018

Appl Spectrosc

375

233

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Until very recently, handheld spectrometers were the domain of major analytical and security instrument companies, with turnkey analyzers using spectroscopic techniques from X-ray fluorescence (XRF) for elemental analysis (metals), to Raman, mid-infrared, and near-infrared (NIR) for molecular analysis (mostly organics). However, the past few years have seen rapid changes in this landscape with the introduction of handheld laser-induced breakdown spectroscopy (LIBS), smartphone spectroscopy focusing on medical diagnostics for low-resource areas, commercial engines that a variety of companies can build up into products, hyphenated or dual technology instruments, low-cost visible-shortwave NIR instruments selling directly to the public, and, most recently, portable hyperspectral imaging instruments. Successful handheld instruments are designed to give answers to non-scientist operators; therefore, their developers have put extensive resources into reliable identification algorithms, spectroscopic libraries or databases, and qualitative and quantitative calibrations. As spectroscopic instruments become smaller and lower cost, ''engines'' have emerged, leading to the possibility of being incorporated in consumer devices and smart appliances, part of the Internet of Things (IOT). This review outlines the technologies used in portable spectroscopy, discusses their applications, both qualitative and quantitative, and how instrument developers and vendors have approached giving actionable answers to non-scientists. It outlines concerns on crowdsourced data, especially for heterogeneous samples, and finally looks towards the future in areas like IOT, emerging technologies for instruments, and portable hyphenated and hyperspectral instruments.

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“…This concentric relay design (cFRET) was used for multiplexed protease sensing [34]. While the attachment schemes for these systems are relatively simple, analysis can become difficult because the dyes can interact with each other as well as the quantum dot [28,193]. In 2017, a three-acceptor cFRET system was demonstrated by attaching three different enzyme cleavable peptides labeled with three discrete dyes to a QD donor [28].…”

Section: Multiplexed Sensingmentioning

confidence: 99%

Sensing with photoluminescent semiconductor quantum dots

Chern

Kays

Bhuckory

et al. 2019

Methods Appl. Fluoresc.

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Fluorescent sensors benefit from high signal-to-noise and multiple measurement modalities, allowing for a multitude of applications and flexibility of design. Semiconductor nanocrystal quantum dots (QDs) are excellent fluorophores for sensors because of their extraordinary optical properties. They have high thermal and photochemical stability compared to organic dyes or fluorescent proteins and are extremely bright due to their large molar cross-sections. In contrast to organic dyes, QD emission profiles are symmetric, with relatively low full width half maxima. In addition, the size tunability of their emission color, which is a result of quantum confinement, make QDs exceptional emitters with high color purity from the ultraviolet to near infrared wavelength range. The role of QDs in sensors ranges from simple fluorescent tags, as used in immunoassays, to intrinsic sensors that utilize the inherent photophysical response of QDs to fluctuations in temperature, electric field or ion concentration. In more complex configurations, QDs and biomolecular recognition moieties like antibodies are combined with a third component to transduce the optical signal via energy transfer. QDs can act as donors, acceptors, or both in energy transfer-based sensors using Förster resonance energy transfer (FRET), nanometal surface energy transfer (NSET), or charge or electron transfer. The changes in both spectral response and photoluminescent lifetimes have been successfully harnessed to produce more sensitive sensors and multiplexed devices. While technical challenges related to biofunctionalization and the high cost of laboratory-grade fluorimeters have thus far prevented broad implementation of QD-based sensing in clinical or commercial settings, improvements in bioconjugation methods and detection schemes, including using simple consumer devices like cell phone cameras, are lowering the barrier to broad use of more sensitive QD-based devices.

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Energy Transfer Pathways in a Quantum Dot-Based Concentric FRET Configuration

Cited by 28 publications

References 62 publications

Energy Transfer with Semiconductor Quantum Dot Bioconjugates: A Versatile Platform for Biosensing, Energy Harvesting, and Other Developing Applications

Energy Transfer with Semiconductor Quantum Dot Bioconjugates: A Versatile Platform for Biosensing, Energy Harvesting, and Other Developing Applications

Portable Spectroscopy

Sensing with photoluminescent semiconductor quantum dots

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