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Nanopore

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Schematic of Nanopore Internal Machinery and corresponding current blockade during sequencing

A nanopore is a pore of nanometer size. It may, for example, be created by a pore-forming protein or as a hole in synthetic materials such as silicon or graphene.

When a nanopore is present in an electrically insulating membrane, it can be used as a single-molecule detector. It can be a biological protein channel in a high electrical resistance lipid bilayer, a pore in a solid-state membrane or a hybrid of these – a protein channel set in a synthetic membrane. The detection principle is based on monitoring the ionic current passing through the nanopore as a voltage is applied across the membrane. When the nanopore is of molecular dimensions, passage of molecules (e.g., DNA) cause interruptions of the "open" current level, leading to a "translocation event" signal. The passage of RNA or single-stranded DNA molecules through the membrane-embedded alpha-hemolysin channel (1.5 nm diameter), for example, causes a ~90% blockage of the current (measured at 1 M KCl solution).[1]

It may be considered a Coulter counter for much smaller particles.[2]

Types

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Organic

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  • Nanopores may be formed by pore-forming proteins,[3] typically a hollow core passing through a mushroom-shaped protein molecule. Examples of pore-forming proteins are alpha hemolysin, aerolysin, and MspA porin. In typical laboratory nanopore experiments, a single protein nanopore is inserted into a lipid bilayer membrane and single-channel electrophysiology measurements are taken. Newer pore-forming proteins have been extracted from bacteriophages for study into their use as nanopores. These pores are generally selected due to their diameter being above 2 nm, the diameter of double-stranded DNA.[4]
  • Larger nanopores can be up to 20 nm in a diameter. These pores allow small molecules like oxygen, glucose and insulin to pass however they prevent large immune system molecules like immunoglobins from passing. As an example, rat pancreatic cells are microencapsulated, they receive nutrients and release insulin through nanopores being totally isolated from their neighboring environment i.e. foreign cells. This knowledge can help to replace nonfunctional islets of Langerhans cells in the pancreas (responsible for producing insulin), by harvested piglet cells. They can be implanted underneath the human skin without the need of immunosuppressants which put diabetic patients at a risk of infection.

Inorganic

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  • Solid-state nanopores are generally made in silicon compound membranes, one of the most common being silicon nitride. The second type of widely used solid-state nanopores are glass nanopores fabricated by laser-assisted pulling of glass capillary.[5] Solid-state nanopores can be manufactured with several techniques including ion-beam sculpting,[6] dielectric breakdown,[7] electron beam exposure using TEM[8] and Ion track etching.[9]
  • More recently, the use of graphene[10] as a material for solid-state nanopore sensing has been explored. Another example of solid-state nanopores is a box-shaped graphene (BSG) nanostructure.[11] The BSG nanostructure is a multilayer system of parallel hollow nanochannels located along the surface and having quadrangular cross-section. The thickness of the channel walls is approximately equal to 1 nm. The typical width of channel facets makes about 25 nm.
  • Size-tunable elastomeric nanopores have been fabricated, allowing accurate measurement of nanoparticles as they occlude the flow of ionic current. This measurement methodology can be used to measure a wide range of particle types. In contrast to the limitations of solid-state pores, they allow for the optimization of the resistance pulse magnitude relative to the background current by matching the pore-size closely to the particle-size. As detection occurs on a particle by particle basis, the true average and polydispersity distribution can be determined.[12][13] Using this principle, the world's only commercial tunable nanopore-based particle detection system has been developed by Izon Science Ltd. The box-shaped graphene (BSG) nanostructure can be used as a basis for building devices with changeable pore sizes.[11]

Nanopore based sequencing

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The observation that a passing strand of DNA containing different bases corresponds with shifts in current values has led to the development of nanopore sequencing.[14] Nanopore sequencing can occur with bacterial nanopores as mentioned in the above section as well as with the Nanopore sequencing device(s) is created by Oxford Nanopore Technologies.

Monomer identification

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From a fundamental standpoint, nucleotides from DNA or RNA are identified based on shifts in current as the strand is entering the pore. The approach that Oxford Nanopore Technologies uses for nanopore DNA sequencing labeled DNA sample is loaded to the flow cell within the nanopore. The DNA fragment is guided to the nanopore and commences the unfolding of the helix. As the unwound helix moves through the nanopore, it is correlated with a change in the current value which is measured in thousand times per second. Nanopore analysis software can take this alternating current value for each base detected, and obtain the resulting DNA sequence.[15] Similarly with the usage of biological nanopores, as a constant voltage is applied to the system, the alternating current can be observed. As DNA, RNA or peptides enter the pore, shifts in the current can be observed through this system that are characteristic of the monomer being identified.[16][17]

Ion current rectification (ICR) is an important phenomenon for nanopore. Ion current rectification can also be used as a drug sensor[18][19] and be employed to investigate charge status in the polymer membrane.[20]

Applications to nanopore sequencing

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Apart from rapid DNA sequencing, other applications include separation of single stranded and double stranded DNA in solution, and the determination of length of polymers. At this stage, nanopores are making contributions to the understanding of polymer biophysics, single-molecule analysis of DNA-protein interactions, as well as peptide sequencing. When it comes to peptide sequencing bacterial nanopores like hemolysin, can be applied to both RNA, DNA and most recently protein sequencing. Such as when applied in a study in which peptides with the same Glycine-Proline-Proline repeat were synthesized, and then put through nanopore analysis, an accurate sequence was able to be attained.[21] This can also be used to identify differences in stereochemistry of peptides based on intermolecular ionic interactions. Some configuration changes of protein could also be observed from the translocation curve.[22] Understanding this also contributes more data to understanding the sequence of the peptide fully in its environment.[23] Usage of another bacterial derived nanopore, an aerolysin nanopore, has shown ability having shown similar ability in distinguishing residues within a peptide has also shown the ability to identify toxins present even in proclaimed "very pure" protein samples, while demonstrating stability over varying pH values.[16] A limitation to the usage of bacterial nanopores would be that peptides as short as six residues were accurately detected, but with larger more negatively charged peptides resulted in more background signal that is not representative of the molecule.[24]

Alternate applications

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Since the discovery of track-etched technology in the late 1960s, filter membranes with needed diameter have found application potential in various fields including food safety, environmental pollution, biology, medicine, fuel cell, and chemistry. These track-etched membranes are typically made in polymer membrane through track-etching procedure, during which the polymer membrane is first irradiated by heavy ion beam to form tracks and then cylindrical pores or asymmetric pores are created along the track after wet etching.

As important as fabrication of the filter membranes with proper diameters, characterizations and measurements of these materials are of the same paramount. Until now, a few of methods have been developed, which can be classified into the following categories according to the physical mechanisms they exploited: imaging methods such as scanning electron microscopy (SEM), transmission electron microscopy (TEM), atomic force microscopy (AFM); fluid transport such as bubble point and gas transport; fluid adsorptions such as nitrogen adsorption/desorption (BEH), mercury porosimetry, liquid-vapor equilibrium (BJH), gas-liquid equilibrium (permoporometry) and liquid-solid equilibrium (thermoporometry); electronic conductance; ultrasonic spectroscopy; and molecular transport.

More recently, the use of light transmission technique[25] as a method for nanopore size measurement has been proposed.

See also

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References

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  1. ^ Akeson M, Branton D, Kasianowicz JJ, Brandin E, Deamer DW (December 1999). "Microsecond time-scale discrimination among polycytidylic acid, polyadenylic acid, and polyuridylic acid as homopolymers or as segments within single RNA molecules". Biophysical Journal. 77 (6): 3227–33. Bibcode:1999BpJ....77.3227A. doi:10.1016/S0006-3495(99)77153-5. PMC 1300593. PMID 10585944.
  2. ^ Cornell, B. A.; Braach-Maksvytis, V. L. B.; King, L. G.; Osman, P. D. J.; Raguse, B.; Wieczorek, L.; Pace, R. J. (June 1997). "A biosensor that uses ion-channel switches". Nature. 387 (6633): 580–583. Bibcode:1997Natur.387..580C. doi:10.1038/42432. ISSN 0028-0836. PMID 9177344. S2CID 4348659.
  3. ^ Bayley H (June 2009). "Membrane-protein structure: Piercing insights". Nature. 459 (7247): 651–2. Bibcode:2009Natur.459..651B. doi:10.1038/459651a. PMID 19494904. S2CID 205046984.
  4. ^ Feng, Yanxiao; Zhang, Yuechuan; Ying, Cuifeng; Wang, Deqiang; Du, Chunlei (2015-02-01). "Nanopore-based Fourth-generation DNA Sequencing Technology". Genomics, Proteomics & Bioinformatics. 13 (1): 4–16. doi:10.1016/j.gpb.2015.01.009. ISSN 1672-0229. PMC 4411503. PMID 25743089.
  5. ^ Steinbock LJ, Otto O, Skarstam DR, Jahn S, Chimerel C, Gornall JL, Keyser UF (November 2010). "Probing DNA with micro- and nanocapillaries and optical tweezers". Journal of Physics: Condensed Matter. 22 (45): 454113. Bibcode:2010JPCM...22S4113S. doi:10.1088/0953-8984/22/45/454113. PMID 21339600. S2CID 26928680.
  6. ^ Li J, Stein D, McMullan C, Branton D, Aziz MJ, Golovchenko JA (July 2001). "Ion-beam sculpting at nanometre length scales". Nature. 412 (6843): 166–9. Bibcode:2001Natur.412..166L. doi:10.1038/35084037. PMID 11449268. S2CID 4415971.
  7. ^ Kwok, Harold; Briggs, Kyle; Tabard-Cossa, Vincent (2014-03-21). "Nanopore Fabrication by Controlled Dielectric Breakdown". PLOS ONE. 9 (3): e92880. doi:10.1371/journal.pone.0092880. ISSN 1932-6203. PMC 3962464. PMID 24658537.
  8. ^ Muhammad Sajeer P; Simran; Nukala, Pavan; Manoj M. Varma (2022-11-01). "TEM based applications in solid state nanopores: From fabrication to liquid in-situ bio-imaging". Micron. 162: 103347. doi:10.1016/j.micron.2022.103347. ISSN 0968-4328.
  9. ^ Vlassiouk, Ivan; Apel, Pavel Y.; Dmitriev, Sergey N.; Healy, Ken; Siwy, Zuzanna S. (2009-12-15). "Versatile ultrathin nanoporous silicon nitride membranes". Proceedings of the National Academy of Sciences. 106 (50): 21039–21044. doi:10.1073/pnas.0911450106. ISSN 0027-8424. PMC 2795523. PMID 19948951.
  10. ^ Garaj S, Hubbard W, Reina A, Kong J, Branton D, Golovchenko JA (September 2010). "Graphene as a subnanometre trans-electrode membrane". Nature. 467 (7312): 190–3. arXiv:1006.3518. Bibcode:2010Natur.467..190G. doi:10.1038/nature09379. PMC 2956266. PMID 20720538.
  11. ^ a b Lapshin RV (2016). "STM observation of a box-shaped graphene nanostructure appeared after mechanical cleavage of pyrolytic graphite" (PDF). Applied Surface Science. 360: 451–460. arXiv:1611.04379. Bibcode:2016ApSS..360..451L. doi:10.1016/j.apsusc.2015.09.222. S2CID 119369379.
  12. ^ Roberts GS, Kozak D, Anderson W, Broom MF, Vogel R, Trau M (December 2010). "Tunable nano/micropores for particle detection and discrimination: scanning ion occlusion spectroscopy". Small. 6 (23): 2653–8. doi:10.1002/smll.201001129. PMID 20979105.
  13. ^ Sowerby SJ, Broom MF, Petersen GB (April 2007). "Dynamically resizable nanometre-scale apertures for molecular sensing". Sensors and Actuators B: Chemical. 123 (1): 325–30. doi:10.1016/j.snb.2006.08.031.
  14. ^ Clarke J, Wu HC, Jayasinghe L, Patel A, Reid S, Bayley H (April 2009). "Continuous base identification for single-molecule nanopore DNA sequencing". Nature Nanotechnology. 4 (4): 265–70. Bibcode:2009NatNa...4..265C. doi:10.1038/nnano.2009.12. PMID 19350039.
  15. ^ Li S, Cao C, Yang J, Long YT (2019-01-02). "Detection of Peptides with Different Charges and Lengths by Using the Aerolysin Nanopore". ChemElectroChem. 6 (1): 126–129. doi:10.1002/celc.201800288.
  16. ^ a b Wang Y, Gu LQ, Tian K (August 2018). "The aerolysin nanopore: from peptidomic to genomic applications". Nanoscale. 10 (29): 13857–13866. doi:10.1039/C8NR04255A. PMC 6157726. PMID 29998253.
  17. ^ Bharagava RN, Purchase D, Saxena G, Mulla SI (2019). "Applications of Metagenomics in Microbial Bioremediation of Pollutants". Microbial Diversity in the Genomic Era. Elsevier. pp. 459–477. doi:10.1016/b978-0-12-814849-5.00026-5. ISBN 9780128148495. S2CID 134957124.
  18. ^ Wang J, Martin CR (February 2008). "A new drug-sensing paradigm based on ion-current rectification in a conically shaped nanopore". Nanomedicine. 3 (1): 13–20. doi:10.2217/17435889.3.1.13. PMID 18393663. S2CID 37103067.
  19. ^ Guo Z, Wang J, Wang E (January 2012). "Selective discrimination of small hydrophobic biomolecules based on ion-current rectification in conically shaped nanochannel". Talanta. 89: 253–7. doi:10.1016/j.talanta.2011.12.022. PMID 22284488.
  20. ^ Guo Z, Wang J, Ren J, Wang E (September 2011). "pH-reversed ionic current rectification displayed by conically shaped nanochannel without any modification". Nanoscale. 3 (9): 3767–73. Bibcode:2011Nanos...3.3767G. doi:10.1039/c1nr10434a. PMID 21826328. S2CID 205795031.
  21. ^ Sutherland TC, Long YT, Stefureac RI, Bediako-Amoa I, Kraatz HB, Lee JS (July 2004). "Structure of Peptides Investigated by Nanopore Analysis". Nano Letters. 4 (7): 1273–1277. Bibcode:2004NanoL...4.1273S. doi:10.1021/nl049413e.
  22. ^ Schmid, Sonja; Stömmer, Pierre; Dietz, Hendrik; Dekker, Cees (2021-03-09). "Nanopore electro-osmotic trap for the label-free study of single proteins and their conformations". doi:10.1101/2021.03.09.434634. {{cite journal}}: Cite journal requires |journal= (help)
  23. ^ Schiopu I, Iftemi S, Luchian T (2015-01-13). "Nanopore investigation of the stereoselective interactions between Cu(2+) and D,L-histidine amino acids engineered into an amyloidic fragment analogue". Langmuir. 31 (1): 387–96. doi:10.1021/la504243r. PMID 25479713.
  24. ^ Li S, Cao C, Yang J, Long YT (2019). "Detection of Peptides with Different Charges and Lengths by Using the Aerolysin Nanopore". ChemElectroChem. 6 (1): 126–129. doi:10.1002/celc.201800288.
  25. ^ Yang L, Zhai Q, Li G, Jiang H, Han L, Wang J, Wang E (December 2013). "A light transmission technique for pore size measurement in track-etched membranes". Chemical Communications. 49 (97): 11415–7. doi:10.1039/c3cc45841e. PMID 24169442. S2CID 205842947.

Further reading

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