Surface-Enhanced Raman Scattering Plasmonic Enhancement Using DNA Origami-Based Complex Metallic Nanostructures

Pilo‐Pais, Mauricio; Watson, Anne; Demers, Steven M. E.; LaBean, Thomas H.; Finkelstein, Gleb

doi:10.1021/nl5003069

Cited by 125 publications

(119 citation statements)

References 38 publications

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“…By generating such ordered arrays, the potential for reproducible and sensitive quantitative SERS analyses exists. In addition to the development of patterned arrays (already described), there has also been a great deal of recent research into the development of isolated SERS active nanoparticle dimers 68,[88][89][90][91] and target-triggered, ordered nanoparticle aggregates. 69,[92][93][94][95] Such isolated dimers and ordered aggregates offer the potential of significantly enhanced SERS signals over individual particles or larger ordered arrays, with good reproducibility.…”

Section: Organized Structuresmentioning

confidence: 99%

“…5(h)]. 91 Unlike the previous dimer fabrication methods, the oligonucleotide-specific interactions associated with DNA and RNA allow for much more diverse and complicated structures to be formed. However, the complexity of forming such elegant and well-defined nanostructures is limited by the melting and binding conditions required for each different interaction.…”

Section: Organized Structuresmentioning

confidence: 99%

“…To provide plasmonic nanostructures, the oligonucleotides are functionalized with colloidal metal nanoparticles at specific locations, providing a means of coordinating the nanoparticles with precision limited only by the flexibility of the specific oligonucleotide sequences employed. 91 An alternative approach to controlled aggregation of SERS nanoparticles that have recently seen growth for SERS sensing applications has been analyte-induced or analyte-triggered nanoparticle aggregation-based systems [see Fig. 5(i)].…”

Section: Organized Structuresmentioning

confidence: 99%

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Recent advances in plasmonic nanostructures for sensing: a review

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Section: Organized Structuresmentioning

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Section: Organized Structuresmentioning

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Section: Organized Structuresmentioning

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“…Also direct metallization of origami to form nanoscale wires and other metallic shapes has been investigated widely [20], but this approach does not provide an easy way to produce functional electronic devices. Many groups have demonstrated optical devices based on organizing metallic NPs exhibiting localized surface plasmon resonance [21][22][23][24], but despite the promises only few DNA based electrical devices or studies have been realized [19,[25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Characterization of Emergence of the Coulomb Blockade in a Pearl-Like DNA-AuNP Assembly

Tapio

Toppari

2023

JSAME

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Due to its superior self-assembly properties and vast functionalization possibilities DNA has long been one of the most promising candidates for fabrication of nanoscale electrical components using molecular building blocks. There exist already many demonstrations on optical devices based on organizing metallic nanoparticles (NP) via DNA self-assembly, but despite the promises only few DNA based electrical devices or studies have been realized so far. Here we study the gold NP conjugated and metallized DNA TX-tilestructure, which we recently showed to exhibit the room temperature Coulomb blockade, the pre-requisition for a single electron transistor. The properties of the obtained Coulomb blockade are further characterized via the differential conductance measurements at temperatures ranging from 4.2 K to 10.2 K. The results show sharp blockade plateaus with varying threshold voltages, which yields further evidence of a gating effect by background charges. This strongly indicates that the DNA-NP assembly functions as a single electron transistor. Also, the additional growth of gold NPs and electrodes via chemical gold deposition process, needed to achieve the Coulomb blockade, is studied here in more details, yielding more insight to the process, and thus helping to realize better control of it.

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“…7 Researchers have also studied the formation of hot spots, ie, small regions of highly enhanced EM field, to obtain high SERS intensity. 8,9 Nanostructures either exist in solution phase or are confined on a substrate in the form of a nanofilm or a periodic array. Historically, a large number of studies exist on nanoplasmonic biosensors based on solution phase nanoparticles, where aggregation of nanoparticles is used for the determination of biomolecular interactions.…”

Section: Introductionmentioning

confidence: 99%

Nanoplasmonic biosensors: current perspectives

Shukla¹,

Mukherji

2015

NDD

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Recent advances in nanotechnology and nanofabrication have helped develop a wide variety of nanostructured platforms for use as nanoplasmonic biosensors. These can either be in solution phase or be confined on a substrate in the form of metallic nanofilms or periodic arrays. Plasmonic properties of these nanostructures depend on the size, shape, position, orientation, etc, and can be altered by interaction between probe and target species on the metal surfaces. This property of nanostructures has been exploited in refractometric nanoplasmonic biosensors, surface-enhanced Raman spectroscopy-based biosensors, plasmon-enhanced fluorescence biosensors, etc. These nanoplasmonic biosensors are employed in diverse areas such as clinical diagnosis, biosecurity, food, and environmental monitoring. Among these, clinical diagnosis has attracted the most research and commercial interest. Nanoplasmonic biosensors can detect disease biomarkers using highly specific and selective biological recognition elements on the nanostructured surfaces. Many excellent reviews exist in this area that trace the developments over the past 3 decades. This review focuses on some of the more recent studies on the detection of various disease biomarkers through nanoplasmonic biosensors. In the process, we have described fabrication techniques and biofunctionalization of such biosensors.

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Surface-Enhanced Raman Scattering Plasmonic Enhancement Using DNA Origami-Based Complex Metallic Nanostructures

Cited by 125 publications

References 38 publications

Recent advances in plasmonic nanostructures for sensing: a review

Recent advances in plasmonic nanostructures for sensing: a review

Characterization of Emergence of the Coulomb Blockade in a Pearl-Like DNA-AuNP Assembly

Nanoplasmonic biosensors: current perspectives

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