DNA nanomechanics allows direct digital detection of complementary DNA and microRNA targets

Husale, Sudhir; Persson, Henrik; Şahin, Özgür

doi:10.1038/nature08626

Cited by 142 publications

(131 citation statements)

References 32 publications

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“…The ability to detect trace amounts of target deoxyribonucleic acid (DNA) sequences in a highly selective manner is of evergrowing interest for rapid detection of disease [1][2][3][4][5][6][7][8][9][10][11]. Herein, we report a method for rapid detection of DNA with ultrahigh sensitivity and specificity based on a novel strategy involving a combination of a polymerase chain reaction (PCR) and Au nanoparticles (Au NPs).…”

Section: Introductionmentioning

confidence: 99%

One-pot polymerase chain reaction with gold nanoparticles for rapid and ultrasensitive DNA detection

Cai

Zhang

et al. 2010

Nano Res.

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We report a novel method for rapid, colorimetric detection of a specific deoxyribonucleic acid (DNA) sequence by carrying out a polymerase chain reaction in the presence of gold nanoparticles functionalized with two primers. Extension of the primers when the target DNA is present as a template during the polymerase chain reaction process affords the complementary sequences on the gold nanoparticle surfaces and results in the formation of gold nanoparticle aggregates with a concomitant color change from red to pinkish/purple. This method provides a convenient and straightforward solution for ultrasensitive DNA detection without any further post-treatment of the polymerase chain reaction products being necessary, and is a promising tool for rapid disease diagnostics and gene sequencing.

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Section: Introductionmentioning

confidence: 99%

One-pot polymerase chain reaction with gold nanoparticles for rapid and ultrasensitive DNA detection

Cai

Zhang

et al. 2010

Nano Res.

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“…A recently reported atomic force microscopy approach 32 showed attomolar DNA concentration resolution by label-free imaging of single hybridized DNA molecules, based on the stiff ness diff erences between single-and double-stranded DNA molecules. Compared with that, our method eliminates the requirement for direct contact with the molecules that might cause sample damage.…”

Section: Discussionmentioning

confidence: 99%

Low-concentration mechanical biosensor based on a photonic crystal nanowire array

Peng

Luo

et al. 2011

Nat Commun

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The challenge for new biosensors is to achieve detection of biomolecules at low concentrations, which is useful for early-stage disease detection. Nanomechanical biosensors are promising in medical diagnostic applications. For nanomechanical biosensing at low concentrations, a suffi cient resonator device surface area is necessary for molecules to bind to. Here we present a low-concentration (500 aM sensitivity) DNA sensor, which uses a novel nanomechanical resonator with ordered vertical nanowire arrays on top of a Si / SiO 2 bilayer thin membrane. The high sensitivity is achieved by the strongly enhanced total surface area-to-volume ratio of the resonator (10 8 m − 1 ) and the state-of-the-art mass-per-area resolution (1.8 × 10 − 12 kg m − 2 ). Moreover, the nanowire array forms a photonic crystal that shows strong light trapping and absorption over broad-band optical wavelengths, enabling high-effi ciency broad-band optothermo-mechanical remote device actuation and biosensing on a chip. This method represents a mass-based platform technology that can sense molecules at low concentrations.

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“…13)). However, the link between the observables and the actual property is still not fully understood.…”

Section: Surface Topography and Property Mapsmentioning

confidence: 99%

“…This new technique allows mapping the local elastic modulus 12 with very high sensitivity for variety of materials. 13 Despite the growing importance and potential of such techniques in material science, the link between the actual observables (amplitude, resonance frequency, phase shift, or even force-displacement curves) and the underlying material properties (e.g., local viscoelasticity) remains tenuous. As a consequence, it is still challenging to interpret AFM results and complex models are needed to relate observables to quantities of interest.…”

mentioning

confidence: 99%

Molecular dynamic simulation of tip-polymer interaction in tapping-mode atomic force microscopy

Venturini

Strachan

2013

Journal of Applied Physics

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We present a molecular dynamic study of the interaction between an amorphous silica tip (SiO 2 ) and an amorphous poly-(methyl-methacrylate) substrate under conditions relevant for tapping-mode atomic force microscopy. To capture the actual dynamics of the tip, we use the dynamic contact simulation method [Kim et al., J. Appl. Phys. 112, 094325 (2012)]. We obtain force-displacement relationships both for neat polymer substrates and a sample with a sub-surface nanotube and extract the local stiffness and energy dissipation per cycle. The simulations capture non-trivial aspects of the interaction that originate from the viscoelastic nature of the polymer including an increase in repulsive interaction force during approach with tip velocity and an increase in adhesion during retraction with decreasing tip velocity. Scans of local stiffness and dissipation over the samples reveal intrinsic variability in the amorphous polymer but also the effect of local surface topography on the extracted properties as well as the ability of the method to detect a sub-surface nanotube. This insight and quantitative data should be valuable to interpret the results of atomic force microscopy studies. V C 2013 AIP Publishing LLC. [http://dx

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DNA nanomechanics allows direct digital detection of complementary DNA and microRNA targets

Cited by 142 publications

References 32 publications

One-pot polymerase chain reaction with gold nanoparticles for rapid and ultrasensitive DNA detection

One-pot polymerase chain reaction with gold nanoparticles for rapid and ultrasensitive DNA detection

Low-concentration mechanical biosensor based on a photonic crystal nanowire array

Molecular dynamic simulation of tip-polymer interaction in tapping-mode atomic force microscopy

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