Long-Range Fluorescence Quenching by Gold Nanoparticles in a Sandwich Immunoassay for Cardiac Troponin T

Mayilo, Sergiy; Kloster, Meike; Wunderlich, Michael T.; Lutich, Andrey A.; Klar, Thomas A.; Nichtl, Alfons; Kürzinger, Konrad; Stefani, Fernando D.; Feldmann, Jochen

doi:10.1021/nl903178n

Cited by 194 publications

(173 citation statements)

References 29 publications

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“…Because of their large absorption cross-section, GNPs have a superior quenching efficiency for a broad wavelength range compared to other organic quenchers [12]. Because they have no defined dipole moment, energy transfer occurs for any orientation of the donor relative to the GNP surface, which increases the probability of energy transfer and accounts for the enhanced efficiency.…”

Section: Colorimetric Assaysmentioning

confidence: 99%

Gold-nanoparticle-based biosensors for detection of enzyme activity

Hutter

Maysinger

2013

Trends in Pharmacological Sciences

151

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Section: Colorimetric Assaysmentioning

confidence: 99%

Gold-nanoparticle-based biosensors for detection of enzyme activity

Hutter

Maysinger

2013

Trends in Pharmacological Sciences

151

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“…Especially defined architectures of metallic nano-objects allow to create materials with new physical and chemical properties and effects. Therefore, great efforts have been devoted towards the spatial organization of metallic nanoparticles (NP) because of their potential applications in optics 1 , electronics 2 , magnetics 3 , biosensing 4 and energy conversion 5 . The ability to understand and control position, orientation and geometry of nano-objects such as NPs assembled with nanoscale precision is crucial to tune unique properties such as subwavelength optical guiding 6 or catalytics 7 .…”

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confidence: 99%

Molecular protein adaptor with genetically encoded interaction sites guiding the hierarchical assembly of plasmonically active nanoparticle architectures

et al. 2015

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The control over the defined assembly of nano-objects with nm-precision is important to create systems and materials with enhanced properties, for example, metamaterials. In nature, the precise assembly of inorganic nano-objects with unique features, for example, magnetosomes, is accomplished by efficient and reliable recognition schemes involving protein effectors. Here we present a molecular approach using protein-based 'adaptors/ connectors' with genetically encoded interaction sites to guide the assembly and functionality of different plasmonically active gold nanoparticle architectures (AuNP). The interaction of the defined geometricaly shaped protein adaptors with the AuNP induces the self-assembly of nanoarchitectures ranging from AuNP encapsulation to one-dimensional chain-like structures, complex networks and stars. Synthetic biology and bionanotechnology are applied to co-translationally encode unnatural amino acids as additional site-specific modification sites to generate functionalized biohybrid nanoarchitectures. This protein adaptor-based nanoobject assembly approach might be expanded to other inorganic nano-objects creating biohybrid materials with unique electronic, photonic, plasmonic and magnetic properties.

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“…[1][2][3] In particular the distance dependence of the quenching process of molecular dyes 4 and colloidal quantum dots (QDs) 1,5 created the basis for a plasmon-ruler with an extended range compared to the previously proposed nano-ruler 6 based on FRET between two fluorescent molecules. 7,8 A good understanding of the distance dependence is important for the design of nano-sensors as the transfer efficiency, and consequently the sensitivity of the nano-sensor, drops off strongly with increasing distance.…”

mentioning

confidence: 99%