A Low-Noise Solid-State Nanopore Platform Based on a Highly Insulating Substrate

Lee, Min‐Hyun; Kumar, Ashvani; Park, Kyeong-Beom; Cho, Seong‐Yong; Kim, Hyun-Mi; Lim, Min-Cheol; Kim, Young-Rok; Kim, Ki-Bum

doi:10.1038/srep07448

Cited by 112 publications

(111 citation statements)

References 40 publications

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“…It may be possible to suppress this noise by reducing the area of the freestanding graphene [31], or by the use of multilayered structures [36,42,43]. Glass-based substrates may furthermore represent a good improvement, as low dielectric materials reduce the capacitive noise [44].…”

Section: Ionic Current Detection Through a Graphene Nanoporementioning

confidence: 99%

Graphene nanodevices for DNA sequencing

2016

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Fast, cheap, and reliable DNA sequencing could be one of the most disruptive innovations of this decade as it will pave the way for personalised medicine. In pursuit of such technology, a variety of nanotechnology-based approaches have been explored and established including sequencing with nanopores. Due to its unique structure and properties, graphene provides interesting opportunities for the development of a new sequencing technology. In recent years, a wide range of creative ideas for graphene sequencers have been theoretically proposed and the first experimental demonstrations have begun to appear. Here, we review the different approaches to using graphene nanodevices for DNA sequencing, which involve DNA passing through graphene nanopores, nanogaps, and nanoribbons, and the physisorption of DNA on graphene nanostructures. We discuss the advantages and problems of each of these key techniques, and provide a perspective on the use of graphene in future DNA sequencing technology.

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Section: Ionic Current Detection Through a Graphene Nanoporementioning

confidence: 99%

Graphene nanodevices for DNA sequencing

2016

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“…[17,18] However,t he problem of excess noise,which corresponds to afew tens of pA to 100 pA, [19,20] remains to be resolved. [17,18] However,t he problem of excess noise,which corresponds to afew tens of pA to 100 pA, [19,20] remains to be resolved.…”

Section: Targetingprotein-proteininteractions(ppis)fortherapeuticmentioning

confidence: 99%

“…[20] Blocking the interaction between mouse double minute 2 (MDM2) and p53 transactivation domain (p53TAD) has been an attractive strategy for cancer therapy because it can restore p53 function, resulting in cancer cell apoptosis.U sing this therapeutic strategy,many p53TAD-mimetic lead compounds have been identified for cancer treatment. [20] Thestructure of the N-terminal p53TADbinding domain of MDM2 (PDB code:1 YCR) [23] showed dimensions of 3.1 nm 3.5 nm 4.2 nm, (Figure 1a). [21,22] Nutlin-3 structurally mimics the 15-residue a-helical p53TAD peptide (residues Ser15-Asn29) that binds to MDM2.…”

Section: Targetingprotein-proteininteractions(ppis)fortherapeuticmentioning

confidence: 99%

“…[1,2] Because drug development for enzyme targets has been limited by the difficulties in achieving sufficient specificity,P PI inhibitors with extremely high specificity have recently attracted considerable attention. [20] Blocking the interaction between mouse double minute 2 (MDM2) and p53 transactivation domain (p53TAD) has been an attractive strategy for cancer therapy because it can restore p53 function, resulting in cancer cell apoptosis.U sing this therapeutic strategy,many p53TAD-mimetic lead compounds have been identified for cancer treatment. Nanopore sensors have several unique advantages compared with more conventional techniques,including single-molecule resolution and ultrasensitivity,label-free and real-time measurements,a nd high-throughput detection.…”

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confidence: 99%

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Probing the Small‐Molecule Inhibition of an Anticancer Therapeutic Protein‐Protein Interaction Using a Solid‐State Nanopore

et al. 2016

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Nanopore sensing is an emerging technology for the single-molecule-based detection of various biomolecules.I n this study,w ep robed the anticancer therapeutic p53 transactivation domain (p53TAD)/MDM2 interaction and its inhibition with as mall-molecule MDM2 antagonist, Nutlin-3, using low-noise solid-state nanopores.A lthough the translocation of positively charged MDM2 through an anopore was detected at the applied negative voltage,t his MDM2 translocation was almost completely blocked upon formation of the MDM2/GST-p53TAD complex owing to charge conversion. In combination with NMR data, the nanopore measurements showed that the addition of Nutlin-3 rescued MDM2 translocation, indicating that Nutlin-3 disrupted the MDM2/GST-p53TAD complex, thereby releasing MDM2. Taken together, our results reveal that solid-state nanopores can be av aluable platform for the ultrasensitive,p icomole-scale screening of small-molecule drugs against protein-protein interaction (PPI) targets. Targetingprotein-proteininteractions(PPIs)fortherapeuticinterventions has been an attractive strategy in drug discovery. [1,2] Because drug development for enzyme targets has been limited by the difficulties in achieving sufficient specificity,P PI inhibitors with extremely high specificity have recently attracted considerable attention. Despite advances in various techniques,s uch as nuclear magnetic resonance (NMR), surface plasma resonance (SPR), and fluorescence polarization (FP), the high-throughput screening (HTS) of small-molecule PPI inhibitors is highly challenging owing to several critical limitations:i )the large amount (mg quantities) of sample required for NMR; [3] ii)the low sensitivity of SPR for detection of small-molecule binding to proteins; [4,5] and iii)the requirement for fluorophore labeling in FP.H ence,t here is an eed to develop ar obust HTS methodology to facilitate the discovery of smallmolecule drugs against PPI targets.Nanopore sensing is an emerging single-molecule technique for biomolecule analysis.W henv oltage is applied across ananoscale pore,the translocation of acharged analyte through the nanopore transiently blocks the ionic current, which is characterized by dwell-time and current amplitude. Nanopore sensors have several unique advantages compared with more conventional techniques,including single-molecule resolution and ultrasensitivity,label-free and real-time measurements,a nd high-throughput detection. [6][7][8][9][10][11][12] Although nanopores have been used to characterize the biophysical properties of diverse biomolecules,i ncluding DNA, RNA, and proteins, [9][10][11][12][13][14][15][16] they have never been applied to the screening of small-molecule drugs such as PPI inhibitors.Despite having much lower resolution and sensitivity, solid-state nanopores have advantages over biological protein nanopores,including high stability,awide range of pore sizes, and controllable surface properties. [17,18] However,t he problem of excess noise,which corresponds to afew tens of pA to 100 pA, [19,20] remains ...

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“…The recognition capability of biological nanopores has been extended to enable detection of epigenetic modifications 16–18 , DNA damage 19,20 and RNA sequences 21 . Improvements in nanopore fabrication technology 22–24 , reduction of noise 25–29 , and the use of two-dimensional materials 30–34 have made DNA sequencing with solid-state nanopores feasible, and considerably expanded the repertoire of physical measurements that could be used for DNA sequence recognition 35–42 .…”

Section: Introductionmentioning

confidence: 99%

DNA sequence-dependent ionic currents in ultra-small solid-state nanopores

Comer

Aksimentiev

2016

Nanoscale

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Measurements of ionic currents through nanopores partially blocked by DNA have emerged as a powerful method for characterization of the DNA nucleotide sequence. Although the effect of the nucleotide sequence on the nanopore blockade current has been experimentally demonstrated, prediction and interpretation of such measurements remain a formidable challenge. Using atomic resolution computational approaches, here we show how the sequence, molecular conformation, and pore geometry affect the blockade ionic current in model solid-state nanopores. We demonstrate that the blockade current from a DNA molecule is determined by the chemical identities and conformations of at least three consecutive nucleotides. We find the blockade currents produced by the nucleotide triplets to vary considerably with their nucleotide sequence despite having nearly identical molecular conformations. Encouragingly, we find blockade current differences as large as 25% for single-base substitutions in ultra small (1.6 nm × 1.1 nm cross section; 2 nm length) solid-state nanopores. Despite the complex dependence of the blockade current on the sequence and conformation of the DNA triplets, we find that, under many conditions, the number of thymine bases is positively correlated with the current, whereas the number of purine bases and the presence of both purine and pyrimidines in the triplet are negatively correlated with the current. Based on these observations, we construct a simple theoretical model that relates the ion current to the base content of a solid-state nanopore. Furthermore, we show that compact conformations of DNA in narrow pores provide the greatest signal-to-noise ratio for single base detection, whereas reduction of the nanopore length increases the ionic current noise. Thus, the sequence dependence of nanopore blockade current can be theoretically rationalized, although the predictions will likely need to be customized for each nanopore type.

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A Low-Noise Solid-State Nanopore Platform Based on a Highly Insulating Substrate

Cited by 112 publications

References 40 publications

Graphene nanodevices for DNA sequencing

Graphene nanodevices for DNA sequencing

Probing the Small‐Molecule Inhibition of an Anticancer Therapeutic Protein‐Protein Interaction Using a Solid‐State Nanopore

DNA sequence-dependent ionic currents in ultra-small solid-state nanopores

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