Electrostatic surface plasmon resonance: Direct electric field-induced hybridization and denaturation in monolayer nucleic acid films and label-free discrimination of base mismatches

Heaton, Richard J.; Peterson, Alexander W.; Georgiadis, R.

doi:10.1073/pnas.071623998

Cited by 213 publications

(221 citation statements)

References 25 publications

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“…A significant increase in the rate of hybridization was found by Heaton et al 64 in a study of the reaction of target DNA sequences with probe sequences attached to a gold surface through a thiol link. In the same paper, they also show that denaturation of dsDNA at the surface can be driven by the potential.…”

Section: Discussionmentioning

confidence: 79%

“…71,72 However, in these experiments, the authors were unable to generate sufficient difference to distinguish SNP targets from the perfect match when using linear DNA probes. There are also a few reports on monitoring electrochemical denaturation with other techniques such as SPR 64 and chemiluminescence 73 in which a constant potential was applied 68 and denaturation was monitored with time.…”

Section: Introductionmentioning

confidence: 99%

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SERS-Melting: A New Method for Discriminating Mutations in DNA Sequences

et al. 2008

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Abstract:The reliable discrimination of mutations, single nucleotide polymorphisms (SNPs), and other differences in genomic sequence is an essential part of DNA diagnostics and forensics. It is commonly achieved using fluorescently labeled DNA probes and thermal gradients to distinguish between the matched and mismatched DNA. Here, we describe a novel method that uses surface enhanced (resonance) Raman spectroscopy (SER(R)S) to follow denaturation of dsDNA attached to a structured gold surface. This denaturation is driven either electrochemically or thermally on SERS active sphere segment void (SSV) gold substrates. Using this method, we can distinguish between wild type, a single point mutation (1653C/ T), and a triple deletion (∆F 508) in the CFTR gene at the 0.02 attomole level, and the method can be used to differentiate the unpurified PCR products of the wild type and ∆F 508 mutation. Our method has the potential to provide small, rapid, sensitive, reproducible platforms for detecting genetic variations and sequencing genes.

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Section: Discussionmentioning

confidence: 79%

Section: Introductionmentioning

confidence: 99%

SERS-Melting: A New Method for Discriminating Mutations in DNA Sequences

et al. 2008

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“…²íø³ àâòîðè äîñÿãàëè óñï³øíî¿ ã³áðèäèçàö³¿ â 1 M NaCl ïðîòÿãîì 14 ãîä. [27], àáî â 50 ìM ôîñôàòíîìó áóôåð³ (pH 7.0), ùî ì³ñòèâ 100 ìM K 2 SO 4 [26], àáî â 10 ìM Tris (pH 7.3), ùî ì³ñòèâ 50 ìM NaCl, ïðîòÿ-ãîì 1 ãîä. [28].…”

Section: åêñïåðèìåíòàëüíà ÷àñòèíàunclassified

Formation and Investigations of Bioselective Element of Surface Plasmon Resonance Sensor for Recognition of Specific Oligonucleotide Sequences

Rachkov¹,

Holodova²,

Dybkov³

et al. 2009

SEMST

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Àíîòàö³ÿ. Á³îñåëåêòèâíèé åëåìåíò ñåíñîðà ïîâåðõíåâîãî ïëàçìîííîãî ðåçîíàíñó (ÏÏÐ) äëÿ ðîçï³çíàâàííÿ îë³ãîíóêëåîòèäíèõ ïîñë³äîâíîñòåé, ïîâ'ÿçàíèõ ç ã³áðèäíèì ãåíîì bcrabl, ñòâîðåíî øëÿõîì ³ììîá³ë³çàö³¿ íà ñåíñîðí³é ïîâåðõí³ ò³îëüîâàíèõ îäíîëàíöþãîâèõ îë³-ãîíóêëåîòèä³â òà 6-ìåðêàïòî-1-ãåêñàíîëó. Îë³ãîíóêëåîòèä ç 24 îñíîâ, ÿêèé ðåïðåçåíòóº ä³-ëÿíêó ñòèêóâàííÿ ã³áðèäíîãî ãåíà ³ ñêëàäàºòüñÿ ç îäíàêîâèõ çà äîâaeèíîþ ôðàãìåíò³â îáîõ âèõ³äíèõ ãåí³â, áóâ âèêîðèñòàíèé ÿê ïðîáà äëÿ ³ììîá³ë³çàö³¿ íà ñåíñîðí³é ïîâåðõí³. Â³äá³ð ïîñë³äîâíîñò³ öüîãî îë³ãîíóêëåîòèäó áàçóâàâñÿ íà GC ñêëàä³ òà çäàòíîñò³ äî âíóòð³øíüî-òà ì³aeìîëåêóëÿðíèõ âçàºìîä³é, òåîðåòè÷íî ïåðåäáà÷åíî¿ çà äîïîìîãîþ âåá-ñåðâåðà DINAMelt. Ôîðìóâàííÿ á³îñåëåêòèâíîãî åëåìåíòó ³ íàñòóïí³ åòàïè ã³áðèäèçàö³¿ ç êîìïëåìåíòàðíèìè îë³ãîíóêëåîòèäàìè êîíòðîëþâàëè â ðåaeèì³ ðåàëüíîãî ÷àñó, êîðèñòóþ÷èñü åêñïåðèìåíòàëü-íèì ìàêåòîì ñïåêòðîìåòðà "Ïëàçìîí ÏÏÐ-4ì", ðîçðîáëåíîãî â ²íñòèòóò³ ô³çèêè íàï³âïðî-â³äíèê³â ÍÀÍ Óêðà¿íè. Áóëî ïîêàçàíî, ùî ò³îëüîâàí³ îäíîëàíöþãîâ³ îë³ãîíóêëåîòèäè modPh óñï³øíî ³ììîá³ë³çóþòüñÿ íà çîëîò³é ïîâåðõí³ âèì³ðþâàëüíî¿ êîì³ðêè ñïåêòðîìåòðà ÏÏÐ ó 0,5 M KH 2 PO 4 (ðÍ 3,8). Ì³ae ³ììîá³ë³çîâàíèìè mod-Ph òà êîìïëåìåíòàðíèìè îë³ãîíóêëåî-òèäàìè P1 â³äáóâàëàñÿ ñïåöèô³÷íà ã³áðèäèçàö³ÿ, â òîé ÷àñ ÿê ââåäåííÿ íåêîìïëåìåíòàðíèõ îë³ãîíóêëåîòèä³â ñåíñîðíîãî â³äãóêó íå âèêëèêàëè. Åêñïåðèìåíòàëüí³ ñåíñîðí³ â³äãóêè, îò-ðèìàí³ ïðè âçàºìîä³ÿõ äîñë³äaeóâàíèõ îë³ãîíóêëåîòèä³â íà ñåíñîðí³é ïîâåðõí³ äîñèòü äîáðå óçãîäaeóþòüñÿ ç òåîðåòè÷íèìè ðîçðàõóíêàìè òåðìîäèíàì³÷íèõ ïàðàìåòð³â öèõ âçàºìîä³é.Êëþ÷îâ³ ñëîâà: ïîâåðõíåâèé ïëàçìîííèé ðåçîíàíñ, ã³áðèäèçàö³éíèé ÄÍÊ-ñåíñîð, á³îñåëåêòèâíèé åëåìåíò, ãåí bcr-abl FORMATION AND INVESTIGATIONS OF BIOSELECTIVE ELEMENT OF SURFACE PLASMON RESONANCE SENSOR FOR RECOGNITION OF SPECIFIC OLIGONUCLEOTIDE SEQUENCESA. E. Rachkov, Yu. V. Holodova, M. V. Dybkov, G. D. Telegeev, A. P. Soldatkin Abstract. A bioselective element of the surface plasmon resonance (SPR) sensor for recognition of oligonucleotide sequences related to the hybrid gene bcr-abl was prepared by immobilization of thiol-derivatized single-stranded oligonucleotides and 6-mercapto-1-hexanol on the sensor surface.

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“…reaction kinetics of biomolecules in the presence of electric fields. Such experiments were performed by Georgiadis et al and Heaton et al to monitor the in situ hybridization of DNA in the presence of different electrochemical fields [114,120,121]. A further and recent use of EC-SPR was the characterization Figure 13.…”

Section: Electrochemical Surface-plasmon Resonance (Ec-spr)mentioning

confidence: 99%

“…The surface concentration or mass coverage of which can then be calculated using the de Feijter formula [111,112]. SPR biosensors can be used in the determination of a number of surface binding interactions, such as: small molecule adsorption [109], protein adsorption on self-assembled monolayers, antibody-antigen binding, DNA and RNA hybridization [113,114], protein-DNA interactions [106], binding kinetics, affinity constants, equilibrium constants, as well as receptor-ligand interactions in immunosensing [105,115] and many more.…”

Section: Electrochemical Surface-plasmon Resonance (Ec-spr)mentioning

confidence: 99%

Electrochemical Biosensors - Sensor Principles and Architectures

Grieshaber

MacKenzie

Vörös

et al. 2008

Sensors

839

636

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Quantification of biological or biochemical processes are of utmost importance for medical, biological and biotechnological applications. However, converting the biological information to an easily processed electronic signal is challenging due to the complexity of connecting an electronic device directly to a biological environment. Electrochemical biosensors provide an attractive means to analyze the content of a biological sample due to the direct conversion of a biological event to an electronic signal. Over the past decades several sensing concepts and related devices have been developed. In this review, the most common traditional techniques, such as cyclic voltammetry, chronoamperometry, chronopotentiometry, impedance spectroscopy, and various field-effect transistor based methods are presented along with selected promising novel approaches, such as nanowire or magnetic nanoparticle-based biosensing. Additional measurement techniques, which have been shown useful in combination with electrochemical detection, are also summarized, such as the electrochemical versions of surface plasmon resonance, optical waveguide lightmode spectroscopy, ellipsometry, quartz crystal microbalance, and scanning probe microscopy. The signal transduction and the general performance of electrochemical sensors are often determined by the surface architectures that connect the sensing element to the biological sample at the nanometer scale. The most common surface modification techniques, the various electrochemical transduction mechanisms, and the choice of the recognition receptor molecules all influence the ultimate sensitivity of the sensor. New nanotechnology-based approaches, such as the use of engineered ion-channels in lipid bilayers, the encapsulation of enzymes into vesicles, polymersomes, or polyelectrolyte capsules provide additional possibilities for signal amplification. In particular, this review highlights the importance of the precise control over the delicate interplay between surface nano-architectures, surface functionalization and the chosen sensor transducer principle, as well as the usefulness of complementary characterization tools to interpret and to optimize the sensor response.

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Electrostatic surface plasmon resonance: Direct electric field-induced hybridization and denaturation in monolayer nucleic acid films and label-free discrimination of base mismatches

Cited by 213 publications

References 25 publications

SERS-Melting: A New Method for Discriminating Mutations in DNA Sequences

SERS-Melting: A New Method for Discriminating Mutations in DNA Sequences

Formation and Investigations of Bioselective Element of Surface Plasmon Resonance Sensor for Recognition of Specific Oligonucleotide Sequences

Electrochemical Biosensors - Sensor Principles and Architectures

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