The nanopore devices closest to being a commercially viable option for sequencing are made out of protein pores and lipid bilayers.
Not exact matches
Using a portable, miniature DNA sequencing
device (Oxford
Nanopore MiniON), the researchers show for the first time that not only can the tool be used for examining environmental samples in extreme and remote settings, but that it can be combined with other methodology to detect active microbial life in the field.
Two years ago, Oxford
Nanopore Technologies demonstrated a revolutionary new sequencing technology at a meeting for genomicists, but it's taken until now for it to show more data and to begin to share its new cheap, hand - held
device with researchers.
In 2014, Oxford
Nanopore rolled out the first commercial nanopore sequencer, a handheld device called
Nanopore rolled out the first commercial
nanopore sequencer, a handheld device called
nanopore sequencer, a handheld
device called MinION.
Oxford
Nanopore's Chief Technology Officer Clive Brown announced an upgrade to its
devices — a new pore the company has been describing in presentations as R9.
Oxford
Nanopore Technologies, facing a lawsuit from Illumina, revealed that this microscopic pore, CsgG, underlies its new
devices.
The research team tested a new
device called MinION, produced by Oxford
Nanopore Technologies Ltd..
New
nanopore DNA sequencing technology on a
device the size of a USB stick could be used to diagnose infection — according to new research from the University of East Anglia and Public Health England.
After this course you should be able to: - Prepare libraries from genomic DNA for amplicon or whole genome approaches to
nanopore sequencing - Run ONT
devices and assess sequencing performance during a run - Understand the basics of ONT data handling and analysis - Analyse and interpret ONT amplicon data and whole genomic data from bacterial samples
Introduction to ONT
devices and latest technology Wet lab training and best practices for sample quality and library preparation for
Nanopore sequencing Running MinKNOW and real - time sequencing data handling Introduction to basecalling and analysis tools (ONT and opens source) for analysis of ONT data
Wang said the remaining hurdles to commercialization include the fabrication of a dense enough crossbar
device to address individual bits and a way to control the size of the
nanopores.
The Oxford
Nanopore Technologies MinION ™ sequencer is a small, portable, low cost
device that is accessible to labs of all sizes and attractive for in - the - field sequencing experiments.
Motivation: Oxford
Nanopore's MinION
device has matured rapidly and is now capable of producing over one million reads and several gigabases of sequence data per run.
The MinION
device by Oxford
Nanopore is the first portable sequencing
device.
The Oxford
Nanopore MinION Mk1B is a portable 90 g
device that sequences DNA directly at 450 bases / second generating sequence reads in excess of 400 kb.
The MinION is a portable
device that uses
nanopore technology and can sequence long DNA molecules.
Oxford
Nanopore Technologies» nanopore sequencing device, the MinION, holds the promise of sequencing ultra-long DNA fragments
Nanopore Technologies»
nanopore sequencing device, the MinION, holds the promise of sequencing ultra-long DNA fragments
nanopore sequencing
device, the MinION, holds the promise of sequencing ultra-long DNA fragments > 100kb.
Motivation: The Oxford
Nanopore MinION sequencer, currently in pre-release testing through the MinION Access Programme (MAP), promises long reads in real - time from a cheap, compact, USB
device.
Background: The introduction of the MinIONTM sequencing
device by Oxford
Nanopore Technologies may greatly accelerate whole genome sequencing.
In
nanopore sequencing
devices, electrolytic current signals are sensitive to base modifications, such as 5 - methylcytosine (5 - mC).
Real - time analysis of
nanopore - based metagenomic sequencing from orthopaedic
device infection
Portable DNA sequencers such as the Oxford
Nanopore MinION
device have the potential to be truly disruptive technologies, facilitating new approaches and analyses and, in some cases, taking sequencing out of the lab and into the field.
In experimental and prototype
nanopore sequencing
devices it has been shown that the electrolytic current signals are sensitive to base modifications, such as 5 - methylcytosine.
Motivation: The MinION
device by Oxford
Nanopore is the first portable sequencing
device.
Motivation: The Oxford
Nanopore MinION
device represents a unique sequencing technology.