DNA Translocations through Nanopores under Nanoscale Preconfinement

Briggs, Kyle; Madejski, Gregory R.; Magill, Martin; Kastritis, Konstantinos; Haan, Hendrick W. de; McGrath, James L.; Tabard‐Cossa, Vincent

doi:10.1021/acs.nanolett.7b03987

Cited by 68 publications

(83 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The method of manufacture will create silicon nanomembranes with different nanopore features, especially when comparing self-assembly processes [ 1 , 2 , 19 ] to direct patterning techniques [ 18 , 20 ]. In biological applications, the shapes and sizes of nanopores in silicon nanomembranes are particularly important in DNA sensing [ 18 , 19 , 21 ], dielectrophoretic applications [ 22 ], and ultrafiltration [ 8 ]. Many software tools have been developed to aid the reconstruction of electron tomography data, such as TomoJ [ 23 ] or IMOD [ 24 ], and these packages are often freely accessible online.…”

Section: Introductionmentioning

confidence: 99%

“…This permits a more realistic analysis of flow behavior than can be achieved with simple cylindrical or conical models that have been used [ 6 , 7 , 25 ]. Our method of reconstruction and simulation could readily be adapted to the detailed study of electric field lines around pores, providing insights for applications such as electroosmostic pumping [ 26 ], dielectrophoresis [ 22 ], and molecular sensing [ 21 ].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

TEM Tomography of Pores with Application to Computational Nanoscale Flows in Nanoporous Silicon Nitride (NPN)

et al. 2018

Self Cite

View full text Add to dashboard Cite

Silicon nanomembrane technologies (NPN, pnc-Si, and others) have been used commercially as electron microscopy (EM) substrates, and as filters with nanometer-resolution size cut-offs. Combined with EM, these materials provide a platform for catching or suspending nanoscale-size structures for analysis. Usefully, the nanomembrane itself can be manufactured to achieve a variety of nanopore topographies. The size, shapes, and surfaces of nanopores will influence transport, fouling, sieving, and electrical behavior. Electron tomography (ET) techniques used to recreate nanoscale-sized structures would provide an excellent way to capture this variation. Therefore, we modified a sample holder to accept our standardized 5.4 mm × 5.4 mm silicon nanomembrane chips and imaged NPN nanomembranes (50–100 nm thick, 10–100 nm nanopore diameters) using transmission electron microscopy (TEM). After imaging and ET reconstruction using a series of freely available tools (ImageJ, TomoJ, SEG3D2, Meshlab), we used COMSOL Multiphysics™ to simulate fluid flow inside a reconstructed nanopore. The results show flow profiles with significantly more complexity than a simple cylindrical model would predict, with regions of stagnation inside the nanopores. We expect that such tomographic reconstructions of ultrathin nanopores will be valuable in elucidating the physics that underlie the many applications of silicon nanomembranes.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

TEM Tomography of Pores with Application to Computational Nanoscale Flows in Nanoporous Silicon Nitride (NPN)

et al. 2018

Self Cite

View full text Add to dashboard Cite

show abstract

“…The selected conformation positions within a tridimensional space, regarding to its rotation, torsion, or twist which needs to be lower than its initial conformation in study [65]. About the computational methods used in nanotechnology, we can highlight several studies in different nanostructures, such as h-BN and BNNTs, explored in several technology areas such as DNA sequencing [66][67][68][69][70], water treatment [71][72][73][74], piezoelectric properties [75,76], and drug delivery [77][78][79], among others. For instance, the cisplatin (CP) is a well-known agent chemotherapeutic that acts directly on DNA causing defects in the cell repair mechanism and leading to apoptosis.…”

Section: Computational Simulation Perspectives Of Boron Nitride Nanotmentioning

confidence: 99%

Functionalized Boron Nitride Applications in Biotechnology

Ribeiro¹,

Randow²,

Vilela³

et al. 2020

Recent Advances in Boron-Containing Materials

View full text Add to dashboard Cite

Due to its interesting chemical, physical, and biological properties, boron nitride has received considerable attention by the scientific and technological communities. However, there is a strong dependency of its structural quality and compatibility in different host systems, regarding its potential applications. The use of these different nanostructures involves several challenges due to their low dispersibility in water and organic solvents; thus, its chemical modification is an important step that gives them specificity. Therefore, the ability to control their surface (physically or chemically) is essential for exploring and building blocks in the nanoengineering of supramolecular structures. In this chapter, we report different boron nitride functionalization processes, as well as their important uses as adjuvants in vaccines, brachytherapy, or drug delivery. Besides some important theoretical studies that have demonstrated the different functionalization possibilities for use in nanomedicine, are also reported.

show abstract

“…The nanofabrication of a complete, high performing nanopore-based DNA sequencing system is currently the main focus of researchers [73,74], with the objective of combining solid state nanopores, sensing nanoelectrodes for the detection of the electrical signal and sample delivery nanofluidics into a rapid and reliable DNA sequencing microchip. The commercial success of Oxford Nanopore Ltd. (see the following paragraph), launching MinION as the first portable commercial label-free sequencer [75], has led researchers to assess its performance in several real-life applications, and to try to identify its current limitations [76][77][78].…”

Section: Nanopore Technology For Label-free Dna Sequencingmentioning

confidence: 99%

Microfluidic Devices for Label-Free DNA Detection

et al. 2018

View full text Add to dashboard Cite

Sensitive and specific DNA biomarker detection is critical for accurately diagnosing a broad range of clinical conditions. However, the incorporation of such biosensing structures in integrated microfluidic devices is often complicated by the need for an additional labelling step to be implemented on the device. In this review we focused on presenting recent advances in label-free DNA biosensor technology, with a particular focus on microfluidic integrated devices. The key biosensing approaches miniaturized in flow-cell structures were presented, followed by more sophisticated microfluidic devices and higher integration examples in the literature. The option of full DNA sequencing on microfluidic chips via nanopore technology was highlighted, along with current developments in the commercialization of microfluidic, label-free DNA detection devices.

show abstract

DNA Translocations through Nanopores under Nanoscale Preconfinement

Cited by 68 publications

References 53 publications

TEM Tomography of Pores with Application to Computational Nanoscale Flows in Nanoporous Silicon Nitride (NPN)

TEM Tomography of Pores with Application to Computational Nanoscale Flows in Nanoporous Silicon Nitride (NPN)

Functionalized Boron Nitride Applications in Biotechnology

Microfluidic Devices for Label-Free DNA Detection

Contact Info

Product

Resources

About