Add to ORKGToday, hundreds of researchers are working on nanopores, making an impact in both basic science and biotechnology. Proteins remain the most versatile sources of nanopores, based on our ability to engineer them with sub-nanometer precision. Recent work aimed at the construction and discovery of novel pores has included unnatural amino acid mutagenesis and the application of selection techniques. The diversity of structures has now been increased through the development of helix-based pores as well as the better-known β barrels. New developments also include truncated pores, which pierce bilayers through lipid rearrangement, and hybrid pores, which do away with bilayers altogether. Pore dimers, which span two lipid bilayers, have been constru...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
We review the current status of various aspects of biopolymer translocation through nanopores and th...
ABSTRACT: DNA nanotechnology excels at rationally designing bottom-up structures that can functional...
Biological nanopores are an essential element to the success of the lipid bilayer that makes life po...
Diverse nanopore-based technologies have substantially expanded the toolbox for label-free single-mo...
bh en ic molecules, such as proteins. We discuss the use of nano-pores for protein folding and bindi...
Evolution has found countless ways to transport material across cells and cellular compartments sepa...
Nanopore analysis is a very promising technique for many applications, such as the study of intrinsi...
Nanoscopic pores in biological systems – cells, for example – are responsible for regulating the tra...
Protein nanopores have been engineered with chemical or genetic sensing elements for the stochastic ...
Membrane nanopores are key for molecular transport in biology, portable DNA sequencing, label-free s...
Nanopores are key in portable sequencing and research given their ability to transport elongated DNA...
DNA nanotechnology has revolutionised our capability to shape and control three-dimensional structur...
DNA sequencing is of great significance to molecular biology with myriad applications in fields such...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
We review the current status of various aspects of biopolymer translocation through nanopores and th...
ABSTRACT: DNA nanotechnology excels at rationally designing bottom-up structures that can functional...
Biological nanopores are an essential element to the success of the lipid bilayer that makes life po...
Diverse nanopore-based technologies have substantially expanded the toolbox for label-free single-mo...
bh en ic molecules, such as proteins. We discuss the use of nano-pores for protein folding and bindi...
Evolution has found countless ways to transport material across cells and cellular compartments sepa...
Nanopore analysis is a very promising technique for many applications, such as the study of intrinsi...
Nanoscopic pores in biological systems – cells, for example – are responsible for regulating the tra...
Protein nanopores have been engineered with chemical or genetic sensing elements for the stochastic ...
Membrane nanopores are key for molecular transport in biology, portable DNA sequencing, label-free s...
Nanopores are key in portable sequencing and research given their ability to transport elongated DNA...
DNA nanotechnology has revolutionised our capability to shape and control three-dimensional structur...
DNA sequencing is of great significance to molecular biology with myriad applications in fields such...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
We review the current status of various aspects of biopolymer translocation through nanopores and th...