Ultraefficient Cap-Exchange Protocol To Compact Biofunctional Quantum Dots for Sensitive Ratiometric Biosensing and Cell Imaging

Wang, Weili; Guo, Yuan; Tiede, Christian; Chen, Siyuan; Kopytynski, Michal; Kong, Ying; Kulak, Alexander N.; Tomlinson, Darren C.; Chen, Rongjun; McPherson, Michael J.; Zhou, Dejian

doi:10.1021/acsami.6b13807

Cited by 36 publications

(34 citation statements)

References 71 publications

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“…[120] In addition to amphiphilic oligomers, a couple of surfactants are also used to make desirable modifications, including cetyltrimethylammonium bromide (CTAB), [131] gemini surfactants, [132] and pegylated-phospholipids. [133] As previously noted, two types of amphiphilic polymers have been used with reference to this strategy, including phospholipidtype low-molecular-weight polymers and high-molecular-weight polymers. [134] The phospholipid-type low-molecular-weight polymers are able to form oil-in-water micelles using hydrophobic interactions between the lipid hydrophobic portion and the hydrophobic surface ligands of the QDs.…”

Section: Surface Coatings Using Polymer Encapsulationmentioning

confidence: 99%

Quantum Dots: A Review from Concept to Clinic

Kargozar

Hoseini

Milan

et al. 2020

Biotechnology Journal

122

101

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Quantum dots (QDs) are semiconductor materials that have gained great interest due to their unique characteristics like optical properties. They are extensively being used in different areas, including solar cells, light-emitting diodes, laser technology, as well as biological and biomedical applications. In this review, comprehensive information about different aspects of QDs is provided, including their types and classifications, synthesis approaches, in vitro and in vivo toxicity, biological applications, and potentials in clinical applications. With a focus on the biological aspects, the respective in vitro and in vivo studies are collected and presented. Various surface modifications on QDs are discussed as directly influencing their properties like toxicity and optical abilities. Given the promising results, these materials are clinically used for targeted molecular therapy and imaging. However, there are a large number of questions that should be addressed before the wide application of QDs in a clinical setting. Regarding the existing barriers to QDs, suggestions are given and discussed to present an appropriate route for the clinical use of these materials.

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Section: Surface Coatings Using Polymer Encapsulationmentioning

confidence: 99%

Quantum Dots: A Review from Concept to Clinic

Kargozar

Hoseini

Milan

et al. 2020

Biotechnology Journal

122

101

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“…The reduced circulation time and more rapid tumour penetration afforded by smaller binding proteins compared to antibodies provides the potential for a faster and timelier imaging procedure and thus should reduce patient time in hospital. Another approach with promise for in vivo tumour imaging involves dye-conjugated Affimers that have been used in Förster resonance transfer (FRET) experiments (Conway et al 2014 ; Wang et al 2017b ).…”

Section: Binding Reagents For Use As Imaging Toolsmentioning

confidence: 99%

“…The binding region is generated from sequences in two variable loops presented between pairs of β-sheets. Affimers have been raised against a diverse set of targets, thereby demonstrating their utility in many different molecular biology applications, including those related to bio-imaging (Fisher et al 2015 ; Kyle et al 2015 ; Raina et al 2015 ; Sharma et al 2016 ; Arrata et al 2017 ; Koutsoumpeli et al 2017 ; Tiede et al 2017 ; Wang et al 2017b ).…”

Section: Introductionmentioning

confidence: 99%

Alternative reagents to antibodies in imaging applications

et al. 2017

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Antibodies have been indispensable tools in molecular biology, biochemistry and medical research. However, a number of issues surrounding validation, specificity and batch variation of commercially available antibodies have prompted research groups to develop novel non-antibody binding reagents. The ability to select highly specific monoclonal non-antibody binding proteins without the need for animals, the ease of production and the ability to site-directly label has enabled a wide variety of applications to be tested, including imaging. In this review, we discuss the success of a number of non-antibody reagents in imaging applications, including the recently reported Affimer.

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“…The field of fluorescent DNA probes improved considerably with the introduction of inorganic nanoparticles, such as quantum dots (QDs) [ 4 , 5 ] and gold (Au) nanoparticles (AuNPs) [ 6 , 7 , 8 ] as energy donors and acceptors [ 9 ], respectively. As a new kind of luminescent inorganic fluorophores, QDs are being widely used in chemical sensors [ 10 ], DNA detection [ 11 ], cell labeling [ 12 ], and imaging [ 13 ] because they have a broad and continuous excitation spectrum, a narrow size-tunable symmetric emission spectrum, and a high fluorescence quantum yield. AuNPs are widely used in gene delivery [ 14 ] and cell labeling [ 15 ] because they are bioinert, nontoxic, and readily synthesized and functionalized.…”

Section: Introductionmentioning

confidence: 99%

Nanostructure and Corresponding Quenching Efficiency of Fluorescent DNA Probes

et al. 2018

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Based on the fluorescence resonance energy transfer (FRET) mechanism, fluorescent DNA probes were prepared with a novel DNA hairpin template method, with SiO2 coated CdTe (CdTe/SiO2) core/shell nanoparticles used as the fluorescence energy donors and gold (Au) nanoparticles (AuNPs) as the energy acceptors. The nanostructure and energy donor/acceptor ratio in a probe were controlled with this method. The relationship between the nanostructure of the probes and FRET efficiency (quenching efficiency) were investigated. The results indicated that when the donor/acceptor ratios were 2:1, 1:1, and 1:2; the corresponding FRET efficiencies were about 33.6%, 57.5%, and 74.2%, respectively. The detection results indicated that the fluorescent recovery efficiency of the detecting system was linear when the concentration of the target DNA was about 0.0446–2.230 nmol/L. Moreover, the probes showed good sensitivity and stability in different buffer conditions with a low detection limit of about 0.106 nmol/L.

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Ultraefficient Cap-Exchange Protocol To Compact Biofunctional Quantum Dots for Sensitive Ratiometric Biosensing and Cell Imaging

Cited by 36 publications

References 71 publications

Quantum Dots: A Review from Concept to Clinic

Quantum Dots: A Review from Concept to Clinic

Alternative reagents to antibodies in imaging applications

Nanostructure and Corresponding Quenching Efficiency of Fluorescent DNA Probes

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